Intake Air Amount Control System for Internal Combustion Engine and Control System

ABSTRACT

An intake air amount control system for an internal combustion engine, which is capable of ensuring high robustness and improving controllability in intake air amount control, to thereby improve drivability and reduce exhaust emissions. A control system  1  of an internal combustion engine  3 , which variably controls the amount of intake air drawn into cylinders # 1  to # 4  as desired via a variable intake valve actuation assembly  40  includes an ECU  2 . The ECU  2  calculates a cylinder intake air amount Gcyl and a target intake air amount Gcyl_cmd (step  16 ), identifies, based on a controlled object model [equation (2)], a vector θs of all model parameters of the controlled object model with an identification algorithm [equations (8) to (13)], calculates a target auxiliary intake cam phase θmsi_cmd based on the vector θs with a sliding mode control algorithm [equations (15) to (21)] (step  80 ), and controls the variable intake valve actuation assembly  40  according to the target auxiliary intake cam phase θmsi_cmd.

FIELD OF THE INVENTION

The present invention relates to an intake air-amount control system for an internal combustion engine that changes valve timing of an intake valve to thereby change the amount of intake air drawn into the cylinder as desired, and a control system that controls a plant by determining an input to the plant with a control algorithm based on a controlled object model that defines a relationship between the input to the plant and an output from the plant.

BACKGROUND ART

Conventionally, an intake air amount control system for an internal combustion engine, which is described in Patent Literature 1, is known as the intake air amount control system of the above-mentioned kind. The engine has an electromagnetic valve mechanism and a valve lift sensor provided for each cylinder, which changes the valve-closing timing relative to the valve-opening timing of each cylinder as desired. The valve lift sensor detects the amount of valve lift of each cylinder. As described hereinafter, in this intake air amount control system, to control the idling speed, the valve-closing timing of each intake valve is controlled via the electromagnetic valve mechanism, whereby the intake air amount is controlled.

More specifically, the target intake air amount for feedforward control is calculated according to the target engine speed, and further, an average value of valve-closing times of the intake valves of all the cylinders is calculated based on the valve-closing time of each intake valve detected by the valve lift sensor. Then, the maximum value of the absolute values of the differences between the average value and the valve-closing times of the cylinders is calculated. Further, according to the maximum value of the absolute values of the differences, a gain for feedback control is calculated. The target intake air amount for feedback control is calculated according to the gain, and the valve-closing timing of each intake valve is calculated based on the two target intake air amounts for feedback control and feedforward control and so forth and the valve-closing timing of the intake valve is controlled by the calculated valve-closing timing. The valve-closing timing of each intake valve is controlled as described above, whereby the idling speed is controlled such that it converges to a target engine speed.

According to the conventional intake air amount control system, based on the valve-closing time of the intake valve detected by the valve lift sensor, the gain for feedback control is calculated, and based on the calculated gain, the target intake air amount for feedback control is calculated. Further, the valve-closing timing of the intake valve is only controlled based on the target intake air amount for feedback control. Therefore, it is impossible to compensate for dead time of the control system, such as operation delay of the electromagnetic valve mechanism, which degrades the convergence of the idling speed to the target engine speed, and hence controllability is low. What is more, it is impossible to compensate for variation in dynamic characteristics and aging of the control system, such as variation in the dynamic characteristics and aging of the electromagnetic valve mechanism, and drifts of the output from the valve lift sensor caused by aging thereof, which degrades the robustness of the control system. As a consequence, in the conventional intake air amount control system, due to the low controllability and low robustness of the system described above, the intake air amount control becomes unstable, which causes rotational variation, and hence there is a fear that during the idling speed control, engine stall occurs, and the amount of exhaust emissions increases due to the degraded fuel combustion. Further, when the above-described method of controlling the intake air amount control is applied to the intake air amount control in a normal operation load region, torque variation and rotational variation increase and the degree of degradation of the combustion also increases, so that drivability and exhaust emissions are further degraded. This problem becomes conspicuous in a high load region or during lean operation (during execution of EGR).

Further, a control system described in Patent Literature 2 is known as the control system of the above-mentioned kind. The control system controls the air-fuel ratio of an internal combustion engine as a plant, and is comprised of a LAF sensor, an oxygen concentration sensor, a state predictor, an identifier, and a sliding mode controller. The LAF sensor and the oxygen concentration sensor detect parameters indicative of the oxygen concentration of exhaust gases in an exhaust passage of the engine, and are arranged in the exhaust passage at respective locations from the upstream side. In this control system, as the controlled object model, there is employed a discrete time system model to which is inputted the difference (hereinafter referred to as “the LAF difference”) between the detected signal value of the LAF sensor and a reference value and from which is outputted the difference (hereinafter referred to as “the O2 difference”) between the detected signal value of the oxygen concentration sensor and a predetermined target value, as the controlled object motel, whereby a control input for controlling the air-fuel ratio is calculated as follows:

The state predictor calculates a predicted value of the O2 difference with a predetermined prediction algorithm based on the controlled object model, and the identifier identifies the model parameters of the controlled object model by a sequential least-squares method. Further, the sliding mode controller calculates the control input based on the predicted value of the O2 difference and the identified values of the model parameters with a sliding mode control algorithm such that time-series data of the 02 difference as a state variable converges to a value of 0. As a consequence, the air-fuel ratio is controlled such that the detected signal value of the oxygen concentration sensor converges to a predetermined target value. With the sliding mode control algorithm, the control input is calculated as the sum of an equivalent control input, an adaptive law input, and a reaching law input. The adaptive law input is for compensating for a modeling error of the controlled object model.

According to the conventional control system, with the sliding mode control algorithm, the modeling error of the controlled object model is compensated for by the adaptive law input. Therefore, when there occurs a steady-state deviation (offset) between the predicted value of the O2 difference and the actual value of the same, i.e. between the predicted value of the output from the plant and the detected value of the same, the steady-state deviation cannot be compensated for, so that there is a possibility that the steady-state deviation remains. Although such a steady-state deviation does not present problems in the above-mentioned air-fuel ratio control, in control demanding higher control accuracy (e.g. control for positioning an actuator), the control system may fail to achieve the demanded control accuracy due to the influence of the steady-state deviation.

The present invention has been made so as to solve the above problems, and a first object thereof is to provide an intake air amount control system for an internal combustion engine, which is capable of ensuring high robustness and improving controllability in air fuel ratio amount control, to thereby improve drivability and reduce exhaust emissions.

A second object of the invention is to provide a control system which is capable of compensating for a steady-state deviation between a predicted value of an output from a plant and a detected value of the same, to thereby enhance control accuracy.

[Patent Literature 1]

Japanese Laid-Open Patent Publication (Kokai) No. 2001-140661 (pages 5 and 6, FIGS. 6 to 18) [Patent Literature 2]

Japanese Laid-Open Patent Publication (Kokai) No. 2000-179385 (pages 11 to 19, FIG. 3).

DISCLOSURE OF THE INVENTION

To attain the above object, in a first aspect of the present invention, there is provided an intake air amount control system 1 for an internal combustion engine 3, which variably controls an amount of intake air drawn into a cylinder #1 to #4 via a variable intake valve timing device (variable intake valve actuation assembly 40) that changes valve timing of an intake valve 6, as desired, comprising estimated intake air amount-calculating means (ECU 2; steps 16 and 30) for calculating an estimated intake air amount (cylinder intake air amount Gcyl) as an estimated value of the amount of intake air drawn into the cylinder, target intake air amount-setting means (ECU 2; steps 16 and 31 to 33) for setting a target intake air amount Gcyl_cmd as a target to which the intake air amount is to be controlled, identification means (ECU2; onboard identifier 223) for identifying, based on a controlled object model [equation (2)] to which a control command value (target auxiliary intake cam phase θmsi_cmd) for controlling the variable intake valve timing device is inputted and from which the estimated intake air amount is outputted, all model parameters a1, a2, and b1 (vector θs of model parameters) of the controlled object model, with a predetermined identification algorithm [equations (8) to (13)], control command value-calculating means (ECU2; sliding mode controller 224; step 80) for calculating the control command value (target auxiliary intake cam phase θmsi_cmd) based on the identified all model parameters such that the estimated intake air mount converges to the target intake air amount, and control means (ECU 2; second SPAS controller 225; step 75) for controlling the variable intake valve timing device according to the calculated control command value.

With the configuration of this intake air amount control system for an internal combustion engine, based on the controlled object model to which a control command value for controlling the variable intake valve timing device is inputted and from which an estimated intake air amount is outputted, all model parameters of the controlled object model are identified with a predetermined identification algorithm, and the control command value is calculated based on the identified all model parameters such that estimated intake air amount converges to the target intake air amount. That is, the control command value is calculated with an adaptive control algorithm, and hence even when the controlled object suffers from variation in dynamic characteristics thereof or aging, by using an onboard identifier as the identification means, it is possible to cause the dynamic characteristics of the controlled object model to be adapted to actual dynamic characteristics thereof while preventing influence of the variation or the aging, whereby the estimated intake air amount can be caused to quickly and stably converge to the target intake air amount. Thus, in the intake air amount control, it is possible to ensure high robustness and improve controllability, which makes it possible to avoid occurrence of torque variation and rotational variation, to thereby improve combustion state. As a result, it is possible to improve operability and reduce exhaust emissions.

Preferably, the control command value-calculating means calculates a predicted value (predicted intake air amount Pre_Gcyl) of the estimated intake air amount, with a predetermined prediction algorithm [equation (7)], and calculates the control command value further based on the predicted value of the estimated intake air amount.

When the intake air amount is controlled via the variable intake valve timing device as in this intake air amount control system, dead time generally exists between the actual operation of the variable intake valve timing device and the amount of intake air drawn into the cylinder due to response delay of the variable intake valve timing device. Therefore, with the configuration of this preferred embodiment, the predicted value of the estimated intake air amount is calculated with a predetermined prediction algorithm, and the control command value is calculated further according to the predicted value of the estimated intake air amount. This makes it possible to calculate the control command value while compensating for the above-mentioned dead time, whereby it is possible to improve the convergence of the estimated intake air amount to the target intake air amount. As a result, it is possible to further improve drivability and further reduce exhaust emissions.

To attain the above object, in a second aspect of the present invention, there is provided an intake air amount control system 1 for an internal combustion engine 3, which variably controls an amount of intake air drawn into a cylinder #1 to #4 via a variable intake valve timing device that changes valve timing of an intake valve 6, as desired, comprising estimated intake air amount-calculating means (ECU 2, steps 16 and 30) for calculating an estimated intake air amount (cylinder intake air amount Gcyl) as an estimated value of the amount of intake air drawn into the cylinder, target intake air amount-setting means (ECU 2; steps 16 and 31 to 33) for setting a target intake air amount as a target to which the intake air amount is to be controlled, predicted value-calculating means (ECU 2; state predictor 222; step 80) for calculating a predicted value of the estimated intake air amount with a predetermined prediction algorithm [equation (7)], control command value-calculating means (ECU 2; sliding mode controller 224; step 80) for calculating the control command value (target auxiliary intake cam phase θmsi_cmd) such that the estimated intake air amount converges to the target intake air amount, according to the predicted value of the estimated intake air amount, and control means (ECU 2; second SPAS controller 225; step 75) for controlling the variable intake valve timing device according to the calculated control command value.

With the configuration of this intake air control system for an internal combustion engine, the predicted value of the intake air amount is calculated with a predetermined prediction algorithm, and the control command value is calculated based on the predicted value of the estimated intake air amount such that the estimated intake air amount converges to the target intake air amount. Therefore, it is possible to calculate the control command value while compensating for the above-mentioned dead time, which makes it possible to improve the convergence of the estimated intake air amount to the target intake air amount. As a result, it is possible to improve drivability and reduce exhaust emissions.

Preferably, the control command value-calculating means calculates the control command value further with a response-specifying control algorithm [equations (15) to (21)].

With the configuration of this preferred embodiment, the control command value is calculated further with a response-specifying control algorithm. Therefore, it is possible to cause the estimated intake air amount to quickly and stably converge to the target intake air amount while preventing oscillatory and overshooting behaviors, which makes it possible to further improve drivability and further reduce exhaust emissions.

In the first and second aspects of the present invention, it is preferred that the variable intake valve timing device comprises an intake rocker arm 51 that pivotally moves to thereby actuate the intake valve 6 for opening and closing thereof, a movable pivot (pin 51 c) that pivotally movably supports the intake rocker arm, first and second intake camshafts (main and auxiliary intake camshafts 41 and 42) that rotate at the same rotational speed, a variable intake cam phase mechanism (variable auxiliary intake cam phase mechanism 70) that changes a relative phase between the first and second intake camshafts, a first intake cam (main intake cam 43) that is provided on the first intake camshaft (main intake camshafts 41), for rotation along with rotation of the first intake camshaft to thereby pivotally move the intake rocker arm about the pivot, and a second intake cam (auxiliary intake cam 44) that is provided on the second intake camshaft (auxiliary intake camshaft 42), for rotation along with rotation of the second intake camshaft to thereby move the pivot of the intake rocker arm.

With the configuration of this preferred embodiment, in the variable intake valve timing device, the first cam rotates along with rotation of the first intake camshaft, thereby pivotally moving the intake rocker arm about the pivot of the intake rocker arm, whereby the intake valve is actuated for opening and closing thereof. In doing this, the rotation of the second intake cam along with rotation of the second intake camshaft moves the pivot of the intake rocker arm, which makes it possible to change the amount of valve lift the intake valve as desired. Further, the variable intake cam phase mechanism changes the relative phase between the first and second intake camshafts, which makes it possible to change both the valve-closing timing and the amount of valve lift of the intake valve as desired. That is, by using the two intake cams, the two intake camshafts, and the variable intake cam phase mechanism, it is possible to realize a variable intake valve timing device that can change the valve-closing timing and the amount of valve lift of the intake valve as desired.

More preferably, the variable intake cam phase mechanism is formed by a hydraulically-driven variable intake cam phase mechanism that is driven by supply of oil pressure Psd, and the control means controls oil pressure supplied to the hydraulically-driven variable intake cam phase mechanism.

With the configuration of the preferred embodiment, the variable intake cam phase mechanism is formed by a hydraulically-driven intake valve timing device that is driven by supply of oil pressure. Therefore, the variable intake valve timing device itself can be constructed as a hydraulically-drive type. This makes it possible to positively open and close the intake valve in a higher load region than when using e.g. a variable intake valve timing device of a type that drives the valve element of the intake valve by an electromagnetic force of a solenoid, whereby it is possible to positively open and close the intake valve in a higher load region, and reduce power consumption and operation nose of the intake valve.

To attain the second object, in a third aspect of the present invention, there is provided a control system 1 for controlling a plant, comprising output detecting means (ECU 2; air flow sensor 21) for detecting an output (cylinder intake air amount Gcyl) from the plant, target value-setting means (ECU 2; steps 16 and 33) for setting a target value (target intake air amount Gcyl_cmd) of the output from the plant, and prediction means (ECU 2; state predictor 222; step 80) for predicting a predicted value (predicted intake air amount Pre_Gcyl) of the output from the plant, with a predetermined prediction algorithm [equation (7)] which is derived based on a controlled object model [equation (2)] of the plant and defines a relationship between an input (auxiliary intake cam phase θmsi) to the plant, the output (cylinder intake air amount Gcyl), and the predicted value (predicted intake air amount Pre_Gcyl) of the output from the plant, wherein the predetermined prediction algorithm includes a plurality of predictive coefficients α1, α2, β1 to βd, and γ1, the predictive coefficients including a compensation parameter γ1 for compensating for a steady-state deviation between the predicted value of the output from the plant and the output from the plant, as one of an addition term and a subtraction term, the control system further comprising identification means (ECU 2; onboard identifier 223; step 80) for identifying the predictive coefficients (predictive coefficient vector θs) with a predetermined identification algorithm [equations (8) to (13)] such that a difference (identification error ide) between the predicted value of the output from the plant and the detected output from the plant becomes minimum, and control command value-determining means (ECU 2; sliding mode controller 224; step 80) for determining a control command value (target auxiliary intake cam phase θmsi_cmd) for controlling an input to the plant, based on the identified predictive coefficients with a predetermined control algorithm [equations (15) to (21)] such that the detected output from the plant converges to the set target value.

With the configuration of this control system, the predicted value of the output from the plant is predicted with a predetermined prediction algorithm derived based on a controlled object model of the plant and defining a relationship between an input to the plant, an output from the same, and a predicted value of the output. The predetermined prediction algorithm includes a plurality of predictive coefficients, and the predictive coefficients include a compensation parameter for compensating for a steady-state deviation between the predicted value of the output from the plant and the output from the plant as one of an addition term and a subtraction term. Therefore, the predicted value of the output from the plant can be calculate as a value in which the compensation parameter is directly reflected. Further, the predictive coefficients including the compensation parameter are identified with a predetermined identification algorithm such that the difference between the predicted value of the output from the plant predicted as describe above and the detected output from the plant becomes minimum. Therefore, these predictive coefficients can be identified as values which causes the dynamic characteristics of the predicted value of the output from the plant and the dynamic characteristics of the detected output to accurately match each other, whereby the steady-state deviation between the predicted value of the output from the plant and the detected output from the plant can be compensated for. Particularly, since the compensation parameter is included in the predictive coefficients as one of an addition term and a subtraction term, the steady-state deviation between the predicted value of the output from the plant and the detected output from the plant can be effectively compensated for using the compensation parameter. In addition, since the compensation parameter can be directly reflected in the predicted value as described above, it is possible to enhance prediction accuracy of the predicted value. Further, according to the predictive coefficients thus identified, the control command value for controlling the input to the plant is determined such that detected output from the plant converges to the target value, which makes it possible to properly cause the actual output from the plant to converge to a target value.

As described above, with the compensation parameter, it is possible to effectively compensate for the steady-state deviation between the predicted value of the output from the plant and the detected output, and make the prediction of the predicted value more accurate than the prior art. (Throughout the present specification, “detection of the output from the plant” is not limited to direct detection of the output from the plant using a sensor or the like, but includes estimation of the same by calculation.)

Preferably, the predetermined control algorithm is a predetermined response-specifying control algorithm [equations (15) to (21)].

With the configuration of the preferred embodiment, the control command value is determined with a predetermined response-specifying control algorithm such that the output from the plant converges to a target value, and hence it is possible to cause the output from the plant to quickly and stably converge to the target value while preventing oscillatory and overshooting behaviors. As a result, the control accuracy can be further enhanced.

Preferably, with the predetermined response-specifying control algorithm, the control command value is determined [equation (8)] as a total sum of a plurality of command value components (equivalent control input Ueq, reaching law input Urch, and valve control input Uvt), and the command value components include a selection command value component (valve control input Uvt) for selecting, when there are two solutions to the command control value, one of the two solutions.

With the configuration of the preferred embodiment, the control command value is determined with a predetermined response-specifying control algorithm, as a total sum of command value components, and the command value components include a selection command value component for selecting, when there are two solutions to the control command value, one of the two solutions. Using the selection command value component, it is possible to forcibly cause one of the two solutions to be selected as the solution of the control command value, and thereby increase the speed of convergence to the forcibly selected accurate solution e.g. by performing onboard identification of the predictive coefficients, whereby even when the controlled object has a dead time characteristic, it is possible to calculate the forcibly selected accurate solution with stability in a short time period.

To attain the second object, in a fourth aspect of the present invention, there is provided a control system 1 for variably controlling an amount of intake air drawn into a cylinder #1 to #4 of an internal combustion engine 3 via a variable intake valve timing device (variable intake valve actuation assembly 40) that changes valve timing of an intake valve 6, as desired, comprising cylinder intake air amount-detecting means (ECU 2; air flow sensor 21, intake pipe absolute pressure sensor 24; steps 16 and 30) for detecting a cylinder intake air amount Gcyl as an amount of intake air drawn into the cylinder, target value-setting means (ECU 2, steps 16 and 33) for setting a target value (target cylinder intake air amount Pre_Gcyl) of the cylinder intake air amount, and prediction means (ECU 2; state predictor 222; step 80) for predicting a predicted value of the cylinder intake air amount, with a predetermined prediction algorithm [equation (7)] that is derived based on a controlled object model [equation (2)] to which a value (auxiliary intake cam phase θmsi) indicative of valve timing of the intake valve 6 is inputted, the value being set by the variable intake valve timing device, and from which the cylinder intake air amount Gcyl is outputted, and defines a relationship between the value (auxiliary intake cam phase θmsi) indicative of the valve timing of the intake valve, the cylinder intake air amount Gcyl, and the predicted value (predicted intake air amount Pre_Gcyl) of the cylinder intake air amount, wherein the predetermined prediction algorithm includes a plurality of predictive coefficients α1, α2, β1 to βd, and γ1, the predictive coefficients including a compensation parameter γ1 for compensating for a steady-state deviation between the predicted value of the cylinder intake air mount and the cylinder intake air amount, as one of an addition term and a subtraction term, the control system further comprising identification means (ECU 2; 223; step 80) for identifying the predictive coefficients (predictive coefficient vector θs) with a predetermined identification algorithm [equations (8) to (13)] such that a difference (identification error ide) between the predicted value of the cylinder intake air mount and the detected cylinder intake air mount becomes minimum, and control command value-determining means (ECU 2; sliding mode controller 224; step 80) for determining a control command value (target auxiliary intake cam phase θmsi_cmd) for controlling the variable intake valve timing device based on the identified predictive coefficients with a predetermined control algorithm such that the detected cylinder intake air mount converges to the set target value.

With the configuration of this control system, the predicted value of cylinder intake air amount is predicted with a predetermined prediction algorithm that is derived based on a controlled object model to which a value indicative of valve timing of the intake value is inputted, the valve being set by the variable intake valve timing device, and from which the cylinder intake air amount is outputted, and defines a relationship between the value indicative of valve timing of the intake vale, the cylinder intake air mount, and the predicted value of the cylinder intake air amount. The predetermined prediction algorithm includes a plurality of predictive coefficients, and the predictive coefficients include a compensation parameter for compensating for a steady-state deviation between the predicted value of the cylinder intake air amount and the cylinder intake air amount as one of an addition term and a subtraction term. Therefore, the predicted value of the cylinder intake air amount can be calculate as a value in which the compensation parameter is directly reflected. Further, the predictive coefficients including the compensation parameter are identified with a predetermined identification algorithm such that the difference between the predicted value of the cylinder intake air amount predicted as describe above and the detected cylinder intake air amount becomes minimum. Therefore, these predictive coefficients can be identified as values which causes the dynamic characteristics of the predicted value of the cylinder intake air amount and the dynamic characteristics of the detected cylinder intake air amount to match each other with accuracy, whereby the steady-state deviation between the predicted value of the cylinder intake air amount and the detected cylinder intake air amount can be compensated for. Particularly, since the compensation parameter is included in the predictive coefficients as one of a addition term and a subtraction term, as described above, the steady-state deviation between the predicted value of the cylinder intake air amount and the detected cylinder intake air amount can be effectively compensated for. In addition, since the compensation parameter can be directly reflected in the prediction value of the cylinder intake air mount as described above, it is possible to enhance prediction accuracy of the predicted value. Further, according to the predictive coefficients thus identified, the control command value for controlling the variable intake valve timing device is determined such that detected cylinder intake air amount converges to the target value, which makes it possible to properly converge the cylinder intake air amount to converge to the target value.

As described above, with the compensation parameter, it is possible to effectively compensate for the steady-state deviation between the predicted value of the cylinder intake air amount and the detected cylinder intake air amount, and make the prediction of the predicted value of the cylinder intake air amount more accurate than the prior art, whereby the control accuracy can be made higher than the prior art. (Throughout the present specification, “detection of the cylinder intake air amount” is not limited to direct detection of the cylinder intake air amount using a sensor or the like, but includes estimation of the same by calculation.)

Preferably, the predetermined control algorithm is a predetermined response-specifying control algorithm [equations (15) to (21)].

With the configuration of the preferred embodiment, with a predetermined response-specifying control algorithm, the control command value is determined such that the cylinder intake air amount converges to its target value. Therefore, it is possible to cause the cylinder intake air amount to quickly and stably converge to the target value thereof while preventing oscillatory and overshooting behaviors.

Preferably, with the predetermined response-specifying control algorithm, the control command value is determined as a total sum of a plurality of command value components (equivalent control input Ueq, reaching law input Urch, and valve control input Uvt), and the command value components include a selection command value component (valve control input Uvt) for selecting, when there are two solutions to the command control value, one of the two solutions.

With the configuration of the preferred embodiment, the control command value is determined with a predetermined response-specifying control algorithm, as a total sum of command value components, and the command value components include a selection command value component for selecting, when there are two solutions to the control command value, one of the two solutions. Therefore, using the selection command value component, it is possible to forcibly cause one of the two solutions to be selected as the solution of the control command value. Further, although the intake system of the engine is a system having dead time characteristics, e.g. by performing onboard identification of the predictive coefficients, it is possible to increase the speed of convergence to the forcibly selected solution of the control command value. This makes it possible, e.g. when a value for setting the valve timing of the intake valve to delayed closing is selected as the control command value, to calculate the control command value that satisfies the requirements and can cause the intake air amount to converge to the target value, with stability in a short time period.

BRIEF DESCRIPTION OF THE DRAWINGS

[FIG. 1]

A diagram schematically showing the arrangement of an internal combustion engine to which is applied a control system (intake air amount control system/control system) according to an embodiment of the present invention;

[FIG. 2]

A diagram schematically showing the arrangement of a variable intake valve actuation assembly and a variable exhaust valve actuation assembly, for the engine;

[FIG. 3]

A block diagram schematically showing the arrangement of the control system;

[FIG. 4]

A diagram schematically showing the arrangement of a fuel evaporation cooling device;

[FIG. 5]

A diagram schematically showing the arrangement of the variable intake valve actuation assembly and the variable exhaust valve actuation assembly, in plan view;

[FIG. 6]

A diagram schematically showing the arrangement of an intake valve-actuating mechanism of the variable intake valve actuation assembly;

[FIG. 7]

A diagram schematically showing the arrangement of a variable main intake cam phase mechanism;

[FIG. 8]

A diagram schematically showing the arrangement of a variable auxiliary intake cam phase mechanism;

[FIG. 9]

A diagram schematically showing the arrangement of a variation of the variable auxiliary intake cam phase mechanism;

[FIG. 10]

A diagram schematically showing the arrangement of a variable inter-intake cam phase mechanism;

[FIG. 11]

A diagram useful in explaining cam profiles of a main intake cam and an auxiliary intake cam;

[FIG. 12A]

A diagram showing an operating state of the intake valve-actuating mechanism in which an auxiliary intake cam phase θmsi is set to 0 degrees;

[FIG. 12B]

A diagram showing a valve lift curve and the like of an intake valve, which is useful in explaining operation of the intake valve when the auxiliary intake cam phase θmsi is set to 0 degrees;

[FIG. 13A]

A diagram showing an operating state of the intake valve-actuating mechanism in which the auxiliary intake cam phase θmsi is set to 90 degrees;

[FIG. 13B]

A diagram showing a valve lift curve and the like of the intake valve, which is useful in explaining operation of the intake valve when the auxiliary intake cam phase θmsi is set to 90 degrees;

[FIG. 14A]

A diagram showing an operating state of the intake valve-actuating mechanism in which the auxiliary intake cam phase θmsi is set to 120 degrees;

[FIG. 14B]

A diagram showing a valve lift curve and the like of the intake valve, which is useful in explaining operation of the intake valve when the auxiliary intake cam phase θmsi is set to 120 degrees;

[FIG. 15A]

A diagram showing an operating state of the intake valve-actuating mechanism in which the auxiliary intake cam phase θmsi is set to 180 degrees;

[FIG. 15B]

A diagram showing a valve lift curve and the like of the intake valve, which is useful in explaining operation of the intake valve when the auxiliary intake cam phase θmsi is set to 180 degrees;

[FIG. 16]

A diagram showing changes in the amount of the valve lift and the valve timing of the intake valve, which is useful in explaining operation of the intake valve when the auxiliary intake cam phase θmsi is changed from 120 degrees to 180 degrees;

[FIG. 17]

A diagram useful in explaining cam profiles of a main exhaust cam and an auxiliary exhaust cam;

[FIG. 18]

A diagram showing a valve lift curve and the like of an exhaust valve, which is useful in explaining operation of the exhaust valve when an auxiliary exhaust cam phase θmse is equal to 0 degrees;

[FIG. 19]

A diagram showing a valve lift curve and the like of the exhaust valve, which is useful in explaining operation of the exhaust valve when the auxiliary exhaust cam phase θmse is equal to 45 degrees;

[FIG. 20]

A diagram showing a valve lift curve and the like of the exhaust valve, which is useful in explaining operation of the exhaust valve when the auxiliary exhaust cam phase θmse is equal to 90 degrees;

[FIG. 21]

A diagram showing the valve lift curve and the like of the exhaust valve, which is useful in explaining operation of the exhaust valve when the auxiliary exhaust cam phase θmse is equal to 150 degrees holding;

[FIG. 22]

A block diagram schematically showing part of the arrangement of the control system, for control of a throttle valve mechanism, the variable auxiliary intake cam phase mechanism, and the variable inter-intake cam phase mechanism;

[FIG. 23]

A block diagram schematically showing the configuration of an auxiliary intake cam phase controller;

[FIG. 24]

A diagram showing respective groups of mathematical expressions with which a cylinder intake air amount Gcyl is calculated, and mathematical expressions of a prediction algorithm of a state predictor of a first SPAS controller;

[FIG. 25]

A diagram showing mathematical expressions of an identification algorithm of an onboard identifier of the first SPAS controller;

[FIG. 26]

A diagram showing mathematical expressions of a sliding mode control algorithm of a sliding mode controller of the first SPAS controller;

[FIG. 27]

A diagram showing mathematical expressions useful for explaining a method of deriving an equation (19) in FIG. 26;

[FIG. 28]

A diagram showing a phase plane and a switching line useful for explaining the sliding mode control algorithm;

[FIG. 29]

A diagram showing an example of a convergence behavior of a following error Es exhibited when a switching function-setting parameter Ss is changed by the sliding mode controller;

[FIG. 30]

A block diagram schematically showing the configuration of a second SPAS controller;

[FIG. 31]

A diagram showing mathematical expressions of a prediction algorithm of a state predictor of the second SPAS controller;

[FIG. 32]

A diagram showing mathematical expressions of an identification algorithm of an onboard identifier of the second SPAS controller;

[FIG. 33]

A diagram showing mathematical expressions of a sliding mode control algorithm of a sliding mode controller of the second SPAS controller;

[FIG. 34]

A diagram showing pulsation of intake air detected by an air flow sensor;

[FIG. 35]

A schematic diagram useful for explaining a calculation algorithm with which intake air amount variation coefficients Φ#1 to Φ#4 are calculated by an adaptive observer of an inter-intake cam phase controller;

[FIG. 36]

A diagram showing mathematical expressions of the calculation algorithm with which the intake air amount variation coefficients Φ#1 to Φ#4 are calculated by the adaptive observer of the inter-intake cam phase controller;

[FIG. 37]

A block diagram schematically showing the configuration of the adaptive observer;

[FIG. 38]

A diagram showing simulated values Gcyl_OS#1 to Gcyl_OS#4 outputted from a signal generator of the adaptive observer;

[FIG. 39]

A diagram showing mathematical expressions with which differences EΦ#2 to EΦ#4 are calculated by respective differentiators of the inter-intake cam phase controller, and a mathematical expression of a calculation algorithm with which a target inter-intake cam phase θssi#i_cmd is calculated by an intake air variation controller of the inter-intake cam phase controller;

[FIG. 40]

A block diagram schematically showing the configuration of the intake air variation controller;

[FIG. 41]

A block diagram schematically showing the configuration of an auxiliary exhaust cam phase controller;

[FIG. 42]

A diagram showing mathematical expressions of a control algorithm of the auxiliary exhaust cam phase controller;

[FIG. 43]

A flowchart showing a main routine for carrying out an engine control process;

[FIG. 44]

A flowchart showing a subroutine for carrying out a fuel control process;

[FIG. 45]

A diagram showing an example of a map for use in calculation of a demanded drive torque TRQ_eng;

[FIG. 46]

A flowchart showing a subroutine for carrying out a process for calculating the cylinder intake air amount Gcyl and a target intake air amount Gcyl_cmd;

[FIG. 47]

A diagram showing an example of a map for use in calculation of a basic value Gcyl_cmd_base of the target intake air amount;

[FIG. 48]

A diagram showing an example of a table for use in calculation of an air-fuel ratio correction coefficient Kgcyl_af;

[FIG. 49]

A diagram showing an example of a table for use in calculation of a main fuel injection ratio Rt_Pre;

[FIG. 50]

A flowchart showing a subroutine for carrying out a boost pressure control process;

[FIG. 51]

A diagram showing an example of a table for use in calculation of a basic value Dut_wg_base of a control input to a wastegate valve;

[FIG. 52]

A diagram showing an example of a table for use in calculation of a target boost pressure Pc_cmd;

[FIG. 53]

A flowchart showing a subroutine for carrying out an intake valve control process;

[FIG. 54]

A continuation of the FIG. 53 flowchart;

[FIG. 55]

A diagram showing an example of a table for use in calculation of a catalyst warmup value θmsi_cw of a target auxiliary intake cam phase;

[FIG. 56]

A diagram showing an example of a table for use in calculation of a normal operation value θmi_drv of a target main intake cam phase;

[FIG. 57]

A diagram showing an example of a map for use in calculation of a basic value θmsi_base of a target auxiliary intake cam phase;

[FIG. 58]

A flowchart showing a subroutine for carrying out an exhaust valve control process;

[FIG. 59]

A continuation of the FIG. 58 flowchart;

[FIG. 60]

A diagram showing an example of a table for use in calculation of a catalyst warmup value θmse_ast of a target auxiliary exhaust cam phase;

[FIG. 61]

A diagram showing an example of a table for use in calculation of a normal operation value θme_drv of a target main exhaust cam phase;

[FIG. 62]

A flowchart showing a subroutine for carrying out a throttle valve control process;

[FIG. 63]

A diagram showing an example of a table for use in calculation of a catalyst warmup value THcmd_ast of a target opening degree;

[FIG. 64]

A diagram showing an example of a map for use in calculation of a normal operation value THcmd_drv of the target opening degree;

[FIG. 65]

A diagram showing an example of a map for use in calculation of a failsafe value THcmd_fs of the target opening degree;

[FIG. 66]

A timing chart showing an example of operation of the control system executed during starting of the engine and catalyst warmup control;

[FIG. 67]

A diagram showing an example of operation of the control system executed for control of the engine; and

[FIG. 68]

A block diagram schematically showing the arrangement of a variation of the control system.

MODE FOR CARRYING OUT THE INVENTION

The invention will now be described in detail with reference to the drawings showing a preferred embodiment thereof. Referring first to FIGS. 1 and 2, there is schematically shown the arrangement of an internal combustion engine 3 (hereinafter simply referred to as “the engine 3”) to which is applied a control system 1 (intake air amount control system/control system) according to the present embodiment. FIG. 3 schematically shows the arrangement of the control system 1. As shown in FIG. 3, the control system 1 includes an ECU 2. The ECU 2 carries out control processes, as described hereinafter, including a process for control of valve timing of intake valves 6 and exhaust valves 7, based on operating conditions of the engine 3.

The engine 3 is an inline four-cylinder gasoline engine installed on an automotive vehicle, not shown, and has first to fourth cylinders #1 to #4 (see FIG. 5). Further, the engine 3 includes main fuel injection valves 4 (only one of which is shown) and spark plugs 5 (only one of which is shown), provided for the respective cylinders #1 to #4. The main fuel injection valves 4 and the spark plugs 5 are all mounted through respective cylinder heads 3 a. Each main fuel injection valve 4 is electrically connected to the ECU 2, and controlled in respect of a fuel injection amount and fuel injection timing thereof, by a control input from the ECU 2, for direct injection of fuel into the combustion chamber of the associated cylinder.

Further, each spark plug 5 is also electrically connected to the ECU 2. When the spark plug 5 has a high voltage applied thereto based on a signal from the ECU 2 in timing corresponding to ignition timing, the spark plug 5 causes a spark discharge, thereby burning a mixture within the combustion chamber.

Further, the engine 3 includes, on a cylinder-by-cylinder basis, an intake valve 6 and an exhaust valve 7 that open and close an intake port and an exhaust port, respectively, a variable intake valve actuation assembly 40 that actuates the intake valve 6 to open and close the same and at the same time changes the valve timing and the amount of the valve lift of the intake valve 6, and a variable exhaust valve actuation assembly 90 that actuates the exhaust valve 7 to open and close the same and at the same time changes the valve timing and the amount of the valve lift of the exhaust valve 7. Details of the variable intake valve actuation assembly 40 and the variable exhaust valve actuation assembly 90 will be described hereinafter. Further, the intake valve 6 and the exhaust valve 7 are urged in the valve-closing directions by valve springs 6 a and 7 a, respectively.

A magnet rotor 20 a is mounted on a crankshaft 3 b of the engine 3. The magnet rotor 20 a constitutes a crank angle sensor 20 together with an MRE (magnetic resistance element) pickup 20 b. The crank angle sensor 20 delivers a CRK signal and a TDC signal, which are both pulse signals, to the ECU 2 in accordance with rotation of the crankshaft 3 b.

Each pulse of the CRK signal is generated whenever the crankshaft 3 b rotates through a predetermined angle (e.g. 30 degrees). The ECU 2 determines the rotational speed NE of the engine 3 (hereinafter referred to as “the engine speed NE”) based on the CRK signal. The TDC signal indicates that each piston 3 c in the associated cylinder is in a predetermined crank angle position immediately before the TDC position at the start of the intake stroke, and each pulse of the TDC signal is generated whenever the crankshaft 3 b rotates through a predetermined angle (180 degrees in the example of the present embodiment).

In an intake pipe 8 of the engine 3, there are arranged a turbocharger device 10, an intercooler 11, a fuel evaporation cooling device 12, a throttle valve mechanism 16, and so forth, from upstream to downstream in the mentioned order at respective locations of the intake pipe 8.

The turbocharger device 10 is comprised of a compressor blade 10 a housed in a compressor housing provided in an intermediate portion of the intake pipe 8, a turbine blade 10 b housed in a turbine housing provided in an intermediate portion of an exhaust pipe 9, a shaft 10 c integrally formed with the two blades 10 a and 10 b for connection thereof, and a wastegate valve 10 d.

In the turbocharger device 10, when the turbine blade 10 b is driven for rotation by exhaust gases flowing through the exhaust pipe 9, the compressor blade 10 a integrally formed with the turbine blade 10 b is also rotated, whereby intake air within the intake pipe 8 is pressurized, that is, supercharging operation is performed.

Further, the wastegate valve 10 d is provided for opening and closing a bypass exhaust passage 9 a that bypasses the turbine blade 10 b disposed across the exhaust pipe 9, and implemented by a solenoid control valve connected to the ECU 2 (see FIG. 3). The wastegate valve 10 d is changed in the degree of opening thereof by a control input Dut_wg from the ECU 2 to thereby change the flow rate of exhaust gases flowing through the bypass exhaust passage 9 a, in other words, the flow rate of exhaust gases for driving the turbine blade 10 b. Thus, the boost pressure Pc of intake air created by the turbocharger device 10 is controlled.

Further, there is provided an air flow sensor 21 (output-detecting means, cylinder intake air amount-detecting means) in the intake pipe 8 at a location upstream of the compressor blade 10 a. The air flow sensor 21 is formed by a hot-wire air flow meter, for detecting an amount Gth of intake air (hereinafter referred to as “the TH passing intake air amount Gth”) flowing through a throttle valve 17, referred to hereinafter, and delivers a signal indicative of the sensed TH passing intake air amount Gth to the ECU 2.

The intercooler 11 is of a water cooling type. When intake air passes through the intercooler 11, the intercooler 11 cools the intake air whose temperature has been raised by the supercharging operation (pressurizing operation) by the turbocharger device 10.

Further, disposed between the intercooler 11 and the fuel evaporation cooling device 12 in the intake pipe 8 is a boost pressure sensor 22 which is formed e.g. by a semiconductor pressure sensor. The boost pressure sensor 22 detects the pressure of intake air within the intake pipe 8, pressurized by the turbocharger device 10, that is, the boost pressure Pc (absolute pressure), and delivers a signal indicative of the sensed boost pressure Pc to the ECU 2.

The fuel evaporation cooling device 12 evaporates fuel to generate a mixture, and lowers the temperature of intake air through evaporation of the fuel. As shown in FIG. 4, the fuel evaporation cooling device 12 is comprised of a housing 13 provided at an intermediate portion of the intake pipe 8, a large number of lipophilic film plates 14 (only six of which are shown) housed in the housing 13 such that they are parallel to and spaced from each other by a predetermined distance, and an auxiliary fuel injection valve 15.

The auxiliary fuel injection valve 15 is connected to the ECU 2, and controlled in respect of a fuel injection amount and fuel injection timing thereof by a control input from the ECU 2, to thereby inject fuel toward the large number of lipophilic film plates 14. It should be noted that as described hereinafter, a total fuel injection amount TOUT of fuel to be injected from both of the auxiliary fuel injection valve 15 and the main fuel injection valve 4 is determined based on the operating conditions of the engine 3, and the ratio of an amount of fuel to be injected from the main fuel injection valve 4 (main fuel injection ratio Rt_Pre, referred to hereinafter) to the total fuel injection amount TOUT, and the ratio of an amount of fuel to be injected from the auxiliary fuel injection valve 15 to the same are determined based on the operating conditions of the engine 3. Further, lipophilic films having a fuel affinity are formed on the surfaces of the lipophilic film plates 14.

With the above arrangement of the fuel evaporation cooling device 12, fuel injected from the auxiliary fuel injection valve 15 is formed into thin films on the surfaces of the lipophilic film plates 14 by lipophilicity thereof, and then evaporated by the heat of intake air. As a result, a mixture of air and fuel is generated, and the intake air is cooled by being deprived of heat of evaporation used for evaporation of the fuel. A cooling effect provided by the fuel evaporation cooling device 12 makes it possible to enhance charging efficiency and expand a limit of operation of the engine 3 within which knocking does not occur. For example, in a high-load operating condition of the engine 3, a limit of ignition timing beyond which knocking starts to occur can be expanded in an advancing direction by a predetermined crank angle (e.g. 2 degrees), thereby making it possible to increase combustion efficiency.

The throttle valve mechanism 16 includes the throttle valve 17, and a TH actuator 18 for opening and closing the throttle valve 17. The throttle valve 17 is pivotally arranged across an intermediate portion of the intake pipe 8 such that the throttle valve 17 is pivotally moved to change the degree of opening thereof, thereby changing the TH passing intake air amount Gth. The TH actuator 18 is implemented by a combination of a motor, not shown, connected to the ECU 2, and a gear mechanism, not shown, and controlled by a control input DUTY_th, described hereinafter, from the ECU 2 to thereby change the degree of opening of the throttle valve 17.

The throttle valve 17 has two springs (neither of which is shown) mounted thereto for urging the throttle valve 17 in the valve-opening direction and the valve-closing direction, respectively. When the control input DUTY_th is not inputted to the TH actuator 18, the throttle valve 17 is held at a predetermined initial valve opening degree TH_def by the urging forces of the above two springs. The initial valve opening degree TH_def is set to a value (e.g. 7 degrees) which corresponds to an almost fully-closed state, but at the same time ensures the amount of intake air required for starting the engine 3.

In the vicinity of the throttle valve 17 disposed in the intake pipe 8, there is provided a throttle valve opening sensor 23 implemented e.g. by a potentiometer. The throttle valve opening sensor 23 detects the degree of actual opening (hereinafter referred to as “the throttle valve opening”) TH of the throttle valve 17, and delivers an electric signal indicative of the detected throttle valve opening TH to the ECU 2.

A portion of the intake pipe 8 downstream of the throttle valve 17 forms a surge tank 8 a into which is inserted an intake pipe absolute pressure sensor 24 (output-detecting means, cylinder intake air amount-detecting means). The intake pipe absolute pressure sensor 24 is implemented e.g. by a semiconductor pressure sensor, and detects an absolute pressure PBA in the intake pipe 8 (hereinafter referred to as “the intake pipe absolute pressure PBA”), to deliver a signal indicative of the sensed intake pipe absolute pressure PBA to the ECU 2. Further, a portion of the intake pipe 8 downstream of the surge tank 8 a forms an intake manifold 8 b (see FIG. 22) which has four branch portions communicating with the four cylinders #1 to #4, respectively.

On the other hand, in the exhaust pipe 9, there are arranged first and second catalytic converters 19 a and 19 b from upstream to downstream in the mentioned order at respective locations downstream of the turbine blade 10 b. The catalytic converters 19 a and 19 b eliminate NOx, HC, and CO from exhaust gases.

An oxygen concentration sensor (hereinafter referred to as “the O2 sensor”) 26 is inserted into the exhaust pipe 9 between the first and second catalytic converters 19 a and 19 b. The O2 sensor 26 is comprised of a zirconia layer and platinum electrodes, and detects the concentration of oxygen contained in exhaust gases downstream of the first catalytic converter 19 a, to deliver a signal indicative of the detected oxygen concentration to the ECU 2.

Further, a LAF sensor 25 is inserted into the exhaust pipe 9 at a location between the turbine blade 10 b and the first catalytic converter 19 a. The LAF sensor 25 is implemented by combining a sensor similar to the O2 sensor 26 and a detection circuit, such as a linearizer, and detects the concentration of oxygen contained in exhaust gases linearly over a wide range of the air-fuel ratio ranging from a rich region to a lean region, thereby delivering a detection signal proportional to the detected oxygen concentration to the ECU 2. The ECU 2 carries out the air-fuel ratio control in response to the outputs from the LAF sensor 25 and the O2 sensor 26.

Next, a description will be given of the variable intake valve actuation assembly 40 (variable intake valve timing device) mentioned above. Referring to FIGS. 2, 5, and 6, the variable intake valve actuation assembly 40 is comprised of a main intake camshaft 41 and an auxiliary intake camshaft 42, for actuating the intake valves 6, intake valve-actuating mechanisms 50 (only one of which is shown) provided for the respective cylinders, for opening and closing the intake valves 6 in accordance with the rotation of the main and auxiliary intake camshafts 41 and 42, a variable main intake cam phase mechanism 60, a variable auxiliary intake cam phase mechanism 70, and three variable inter-intake cam phase mechanisms 80.

The main intake camshaft 41 (first intake camshaft) is rotatably mounted through the cylinder heads 3 a such that it extends in the direction of arrangement of the cylinders. The main intake camshaft 41 includes main intake cams 43 (first intake cams) provided for the respective cylinders, a sprocket 47 provided at one end of the main intake camshaft 41, a main gear 45 disposed between the main intake cam 43 for the first cylinder #1 and the sprocket 47. The main intake cams 43, the main gear 45, and the sprocket 47 are all coaxially mounted on the main intake camshaft 41 for rotation in unison with the main intake camshaft 41. The sprocket 47 is connected to the crankshaft 3 b by a timing chain 48, whereby the main intake camshaft 41 is rotated clockwise as viewed in FIG. 6 (in a direction indicated by an arrow “Y1”) through 360 degrees as the crankshaft 3 b rotates through 720 degrees.

Further, the variable main intake cam phase mechanism 60 is provided at the one end of the main intake camshaft 41 where the sprocket 47 is mounted. The variable main intake cam phase mechanism 60 continuously advances or retards the relative phase of the main intake camshaft 41 with respect to the sprocket 47, that is, the relative phase θmi of the main intake camshaft 41 (hereinafter referred to as “the main intake cam phase θmi”) with respect to the crankshaft 3 b. This operation of the variable main intake cam phase mechanism 60 will be described in detail hereinafter.

Furthermore, a main intake cam angle sensor 27 is disposed at the other end of the main intake camshaft 41, opposite to the end where the sprocket 47 is mounted. Similarly to the crank angle sensor 20, the main intake cam angle sensor 27 is implemented by a magnet rotor and an MRE pickup (neither of which is shown), and delivers a main intake cam signal, which is a pulse signal, to the ECU 2 along with rotation of the main intake camshaft 41. Each pulse of the main intake cam signal is generated whenever the main intake camshaft 41 rotates through a predetermined cam angle (e.g. one degree), and the ECU 2 calculates (detects) the main intake cam phase θmi based on the main intake cam signal and the CRK signal.

Similarly to the main intake camshaft 41, the auxiliary intake camshaft 42 (second intake camshaft) as well is rotatably supported by the cylinder heads 3 a of the cylinders, and extends parallel to the main intake camshaft 41. The auxiliary intake camshaft 42 has auxiliary intake cams 44 (second intake cams) mounted thereon for the respective cylinders, and an auxiliary gear 46 mounted thereon which has the same number of gear teeth as the number of gear teeth of the main gear 45 and the same diameter as the diameter of the main gear 45. The auxiliary gear 46 is coaxially mounted on the auxiliary intake camshaft 42, for rotation in unison therewith.

Both the main gear 45 and the auxiliary gear 46 are urged by respective urging springs, not shown, such that they are always in mesh with each other, and configured such that backlash of the meshing teeth of the main and auxiliary gears 45 and 46 is prevented from occurring by a backlash-compensating mechanism, not shown. Due to the meshing of teeth of the gears 45 and 46, the auxiliary intake camshaft 42 is rotated counterclockwise as viewed in FIG. 6 (in a direction indicated by an arrow “Y2”) at the same rotational speed as that of the main intake camshaft 41, along with the rotation thereof.

Also, the variable auxiliary intake cam phase mechanism 70 (variable intake cam phase mechanism) is provided at an end of the auxiliary intake camshaft 42 toward the timing chain 48. The variable auxiliary intake cam phase mechanism 70 continuously changes the relative phase of the auxiliary intake camshaft 42 with respect to the main intake camshaft 41, in other words, the relative phase θmsi of the auxiliary intake cam 44 for the first cylinder #1 with respect to the main intake cam 43 for the same (hereinafter referred to as “the auxiliary intake cam phase θmsi”). Details of the variable auxiliary intake cam phase mechanism 70 will be described hereinafter.

Further, an auxiliary intake cam angle sensor 28 is provided at the other end of the auxiliary intake camshaft 42, opposite to the end where the variable auxiliary intake cam phase mechanism 70 is provided. Similarly to the main intake cam angle sensor 27, the auxiliary intake cam angle sensor 28 as well is implemented by a magnet rotor and an MRE pickup (neither of which is shown), and delivers an auxiliary intake cam signal, which is a pulse signal, to the ECU 2 along with rotation of the auxiliary intake camshaft 42. Each pulse of the auxiliary intake cam signal is generated whenever the auxiliary intake camshaft 42 rotates through a predetermined cam angle (e.g. one degree), and the ECU 2 calculates the auxiliary intake cam phase θmsi (relative phase between the first and second intake camshafts; input to the plant, value indicative of the valve timing of the intake valve) based on the auxiliary intake cam signal, the main intake cam signal, and the CRK signal.

Out of the four auxiliary intake cams 44, the auxiliary intake cam 44 for the first cylinder #1 is coaxially mounted on the auxiliary intake camshaft 42, for rotation in unison therewith, while the other auxiliary intake cams 44 for the second to fourth cylinders #2 to #4 are connected to the auxiliary intake camshaft 42 via the variable inter-intake cam phase mechanisms 80, respectively. The variable inter-intake cam phase mechanisms 80 continuously changes the respective relative phases θssi#i of the auxiliary intake cams 44 for the second to fourth cylinders #2 to #4 with respect to the auxiliary intake cam 44 for the first cylinder #1 (hereinafter referred to as “the inter-intake cam phases θssi#i”), independently of each other, which will be described in detail hereinafter. It should be noted that the symbol #i used in the inter-intake cam phases θssi#i represents a cylinder number, and is set such that #i represents any of #2 to #4. The same applies to portions of the following descriptions using the symbol #i.

Furthermore, three #2 to #4 auxiliary intake cam angle sensors 29 to 31 are electrically connected to the ECU 2 (see FIG. 3). The respective #2 to #4 auxiliary intake cam angle sensors 29 to 31 deliver #2 to #4 auxiliary intake cam signals, which are pulse signals, to the ECU 2 along with rotation of the auxiliary intake cams 44 for the second to fourth cylinders #2 to #4. Each pulse of the auxiliary intake cam signals is generated whenever each of the auxiliary intake cams 44 for the second to fourth cylinders #2 to #4 rotates through a predetermined cam angle (e.g. one degree), and the ECU 2 calculates the inter-intake cam phases θssi#i based on the #2 to #4 auxiliary intake cam signals, the auxiliary intake cam signal, the main intake cam signal, and the CRK signal.

Each intake valve-actuating mechanism 50 is comprised of the associated main and auxiliary intake cams 43 and 44, an intake rocker arm 51 for opening and closing the associated intake valve 6, and a link mechanism 52 supporting the intake rocker arm 51. The cam profiles of the main and auxiliary intake cams 43 and 44 will be described hereinafter.

The link mechanism 52 is of a four-joint link type, and is comprised of a first link 53 extending substantially parallel to the intake valve 6, upper and lower second links 54 and 54 arranged parallel to each other, a bias spring 55, and a return spring 56. The first link 53 has a central portion of the intake rocker arm 51 pivotally mounted to a lower end thereof by a pin 51 c, and a rotatable roller 53 a provided at an upper end thereof.

The intake rocker arm 51 has a rotatable roller 51 a provided at an end thereof toward the main intake cam 43, and an adjusting bolt 51 b mounted to an end thereof toward the intake valve 6. Valve clearance between the lower end of the adjusting bolt 51 b and the upper end of the intake valve 6 is set to a predetermined value, referred to hereinafter. Further, the bias spring 55 has one end thereof fixed to the intake rocker arm 51, and the other end thereof fixed to the first link 53. The intake rocker arm 51 is urged by the urging force of the bias spring 55 in the clockwise direction as viewed in FIG. 6, whereby the intake rocker arm 51 is always in abutment with the main intake cam 43 via the roller 51 a.

With the arrangement described above, when the main intake cam 43 rotates clockwise as viewed in FIG. 6, the roller 51 a rolls on the cam surface of the main intake cam 43, whereby the intake rocker arm 51 is pivotally moved clockwise or counterclockwise about the pin 51 c as a pivot according to the cam profile of the main intake cam 43. The pivotal motion of the intake rocker arm 51 causes the adjusting bolt 51 b to vertically reciprocate to open and close the intake valve 6.

Further, each of the upper and lower second links 54 and 54 has one end thereof pivotally connected to the associated cylinder head 3 a via a pin 54 a, and the other end thereof pivotally connected to a predetermined portion of the first link 53 via a pin 54 b. Furthermore, the return spring 56 has one end thereof fixed to the upper second link 54, and the other end thereof fixed to the associated cylinder head 3 a. The upper second link 54 is urged in the counterclockwise direction as viewed in FIG. 6 by the urging force of the return spring 56, whereby the first link 53 is always in abutment with the associated auxiliary intake cam 44 via the roller 53 a.

With the arrangement described above, when the auxiliary intake cam 44 rotates counterclockwise as viewed in FIG. 6, the roller 53 a rolls on the cam surface of the auxiliary intake cam 44, whereby the first link 53 is vertically moved according to the cam profile of the auxiliary intake cam 44. As a result, the pin 51 c as the pivot about which the intake rocker arm 51 is pivotally moved is vertically moved between a lowermost position (position shown in FIG. 6) and an uppermost position (position shown in FIG. 15A) thereof. This changes the position of the adjusting bolt 51 b which is actuated for reciprocating motion by the intake rocker arm 51 when the intake rocker arm 51 is pivotally moved as described hereinabove.

Further, the cam nose of the main intake cam 43 is made higher than that of the auxiliary intake cam 44, and a ratio between the height of the cam nose of the main intake cam 43 and the height of the cam nose of the auxiliary intake cam 44 is set to a value equal to a ratio between the distance from the adjusting bolt 51 b to the center of the roller 51 a and the distance from the adjusting bolt 51 b to the center of the pin 51 c. In other words, the ratio between the heights of the two cam noses is set such that when the intake rocker arm 51 is actuated by the main and auxiliary intake cams 43 and 44, the amount of vertical movement of the adjusting bolt 51 b caused by the cam nose of the main intake cam 43 and the amount of vertical movement of the adjusting bolt 51 b caused by the cam nose of the auxiliary intake cam 44 become equal to each other.

Next, a description will be given of the aforementioned variable main intake cam phase mechanism 60. Referring to FIG. 7, the variable main intake cam phase mechanism 60 includes a housing 61, a three-bladed vane 62, an oil pressure pump 63, and a solenoid valve mechanism 64.

The housing 61 is integrally formed with the sprocket 47 described above, and divided by three partition walls 61 a formed at equal intervals. The vane 62 is coaxially mounted on the end of the main intake camshaft 41 where the sprocket 47 is mounted, such that the vane 62 radially extends outward from the main intake camshaft 41, and rotatably housed in the housing 61. Further, the housing 61 has three advance chambers 65 and three retard chambers 66 each formed between one of the partition walls 61 a and one the three blades of the vane 62.

The oil pressure pump 63 is a mechanical one connected to the crankshaft 3 b. As the crankshaft 3 b rotates, the oil pressure pump 63 draws lubricating oil stored in an oil pan 3 d of the engine 3 via a lower part of an oil passage 67 c, for pressurization, and supplies the pressurized oil to the solenoid valve mechanism 64 via the remaining part of the oil passage 67 c.

The solenoid valve mechanism 64 is formed by combining a spool valve mechanism 64 a and a solenoid 64 b, and connected to the advance chambers 65 and retard chambers 66 via an advance oil passage 67 a and a retard oil passage 67 b such that oil pressure supplied from the oil pressure pump 63 is outputted to the advance chambers 65 and retard chambers 66 as advance oil pressure Pad and retard oil pressure Prt. The solenoid 64 b of the solenoid valve mechanism 64 is electrically connected to the ECU 2, and is responsive to a control input DUTY_ml from the ECU 2, for moving a spool valve element of the spool valve mechanism 64 a within a predetermined range of motion according to the control input DUTY_ml to thereby change both the advance oil pressure Pad and the retard oil pressure Prt.

In the variable main intake cam phase mechanism 60 constructed as above, during operation of the oil pressure pump 63, the solenoid valve mechanism 64 is operated according to the control input DUTY_ml, to supply the advance oil pressure Pad to the advance chambers 65 and the retard oil pressure Prt to the retard chambers 66, whereby the relative phase between the vane 62 and the housing 64 is changed toward an advanced side (i.e. advanced) or changed toward a retarded side (i.e. retarded). As a result, the main intake cam phase θmi described above is continuously advanced or retarded within a predetermined range (e.g. within a range of cam angles from 45 to 60 degrees). It should be noted that the variable main intake cam phase mechanism 60 includes a lock mechanism, not shown, which locks operation of the variable main intake cam phase mechanism 60 when oil pressure supplied from the oil pressure pump 63 is low. More specifically, the variable main intake cam phase mechanism 60 is inhibited from changing the main intake cam phase θmi, whereby the main intake cam phase θmi is locked to a value suitable for idling or starting of the engine 3.

Next, a description will be given of the aforementioned variable auxiliary intake cam phase mechanism 70. Referring to FIG. 8, the variable auxiliary intake cam phase mechanism 70 is comprised of a housing 71, a one-bladed vane 72, an oil pressure piston mechanism 73, and a motor 74.

The housing 71 is integrally formed with the gear 46 of the auxiliary intake camshaft 42, and has a vane chamber 75 defined therein which has a sectoral shape in cross section. The vane 72 is coaxially mounted on the end of the auxiliary intake camshaft 42 toward the timing chain 48 such that it extends outward from the auxiliary intake camshaft 42, and rotatably accommodated in the vane chamber 75. The vane 72 divides the vane chamber 75 into first and second vane chambers 75 a and 75 b.

Further, one end of a return spring 72 a is fixed to the vane 72, and the other end thereof is fixed to the housing 71. The vane 72 is urged by the return spring 72 a in the counterclockwise direction as viewed in FIG. 8, i.e. in the direction of reducing the volume of the first vane chamber 75 a.

On the other hand, the oil pressure piston mechanism 73 includes a cylinder 73 a, and a piston 73 b. The inner space of the cylinder 73 a communicates with the first vane chamber 75 a via an oil passage 76. The inner space of the cylinder 73 a, the oil passage 76, and the first vane chamber 75 a are filled with working oil. Further, the second vane chamber 75 b communicates with the atmosphere.

The piston 73 b has a rack 77 joined thereto. A pinion 78 in mesh with the rack 77 is coaxially mounted on the drive shaft of the motor 74. The motor 74 is electrically connected to the ECU 2, and responsive to a control input DUTY_msi from the ECU 2, for driving the pinion 78 for rotation, whereby the piston 73 b is slid within the cylinder 73 a via the rack 77. This changes oil pressure Psd within the first vane chamber 75 a, and the vane 72 is rotated clockwise or counterclockwise depending on the balance between the oil pressure Psd changed as above and the urging force of the return spring 72 a. As a result, the auxiliary intake cam phase θmsi is continuously advanced or retarded within a predetermined range (e.g. within a range of cam angles from 0 to 180 degrees, referred to hereinafter).

As described above, the variable auxiliary intake cam phase mechanism 70 changes the auxiliary intake cam phase θmsi using the oil pressure piston mechanism 73 and the motor 74 in place of the oil pressure pump 63 and the solenoid valve mechanism 64 which are used for the variable main intake cam phase mechanism 60 described above. This is because the variable auxiliary intake cam phase mechanism 70 is required to be higher in responsiveness than the variable main intake cam phase mechanism 60, since the variable auxiliary intake cam phase mechanism 70 is used for adjustment of the amount of intake air drawn into each cylinder. Therefore, when the variable auxiliary intake cam phase mechanism 70 need not be high in responsiveness (e.g. when required to perform only one of the retarded-closing control and advanced-closing control of the intake valve 6, for control of the valve timing of the intake valve 6, described hereinafter), the oil pressure pump 63 and solenoid valve mechanism 64 may be employed in place of the oil pressure piston mechanism 73 and the motor 74, similarly to the variable main intake cam phase mechanism 60.

It should be noted that as shown in FIG. 9, the variable auxiliary intake cam phase mechanism 70 may be provided with a return spring 72 b for urging the vane 72 in the clockwise direction as viewed in FIG. 9, with an urging force set to the same value as that of the return spring 72 a, and a neutral position, shown in FIG. 9, of the vane 72 may be set to a position corresponding to a value of the auxiliary intake cam phase θmsi to which the auxiliary intake cam phase 0 msi is most frequently controlled. With this configuration of the variable auxiliary intake cam phase mechanism 70, a time period over which the vane 72 is held at its neutral position can be made longer during operation of the variable auxiliary intake cam phase mechanism 70, whereby it is possible to secure a longer time during which the motor 74 is not in operation, thereby making it possible to reduce electrical power consumption.

Next, a description will be given of the aforementioned variable inter-intake cam phase mechanisms 80. Since the three variable inter-intake cam phase mechanisms 80 have the same construction, hereinafter, a variable inter-intake cam phase mechanism 80 for changing an inter-intake cam phase θssi#2 of the auxiliary intake cam 44 for the second cylinder #2 will be described by way of example. The variable inter-intake cam phase mechanism 80 is used for adjusting a steady-state variation in intake air amount between the cylinders, and not required to have high responsiveness. Therefore, this mechanism 80 is configured substantially similarly to the variable main intake cam phase mechanism 60 described above. More specifically, as shown in FIG. 10, the variable inter-intake cam phase mechanism 80 is comprised of a housing 81, a vane 82, an oil pressure pump 83, and a solenoid valve mechanism 84.

The housing 81 is integrally formed with the auxiliary intake cam 44 for the second cylinder #2, and provided with one partition wall 81 a. The vane 82 is coaxially mounted on an intermediate portion of the auxiliary intake camshaft 42, and rotatably housed in the housing 81. Further, the housing 81 has an advance chamber 85 and a retard chamber 86 formed between the partition wall 81 a and opposite inner walls of the vane 82.

Similarly to the aforementioned oil pressure pump 63, the oil pressure pump 83 is a mechanical one connected to the crankshaft 3 b. As the crankshaft 3 b rotates, the oil pressure pump 83 draws lubricating oil stored in the oil pan 3 d of the engine 3 via a lower part of an oil passage 87 c, for pressurization, and supplies the pressurized oil to the solenoid valve mechanism 84 via the remaining part of the oil passage 87 c.

Similarly to the solenoid valve mechanism 64 described above, the solenoid valve mechanism 84 is formed by combining a spool valve mechanism 84 a and a solenoid 84 b, and connected to the advance chamber 85 and the retard chamber 86 via an advance oil passage 87 a and a retard oil passage 87 b such that oil pressure supplied from the oil pressure pump 83 is outputted to the advance chamber 85 and the retard chamber 86 as advance oil pressure Pad and retard oil pressure Prt. The solenoid 84 b of the solenoid valve mechanism 84 is electrically connected to the ECU 2, and is responsive to a control input DUTY_ssi#2 from the ECU 2, for moving a spool valve element of the spool valve mechanism 84 a within a predetermined range of motion according to the control input DUTY_ssi#2 to thereby change both the advance oil pressure Pad and the retard oil pressure Prt.

In the above variable inter-intake cam phase mechanism 80, during operation of the oil pressure pump 83, the solenoid valve mechanism 84 is operated according to the control input DUTY_ssi#2, to supply the advance oil pressure Pad and the retard oil pressure Prt to the advance chamber 85 and the retard chamber 86, respectively, whereby the relative phase between the vane 82 and the housing 84 is advanced or retarded. As a result, the aforementioned inter-intake cam phase θssi#2 is continuously advanced or retarded within a predetermined range (e.g. within a range of cam angles from 0 to 30 degrees). It should be noted that the variable inter-intake cam phase mechanism 80 is provided with a lock mechanism, not shown, which locks operation of the variable inter-intake cam phase mechanism 80 when oil pressure supplied from the oil pressure pump 83 is low. More specifically, the variable inter-intake cam phase mechanism 80 is inhibited from changing the inter-intake cam phase θssi#2, whereby the inter-intake cam phase θssi#2 is locked to a target control value (value of 0, referred to hereinafter) at this time point.

When it is required to control the internal EGR amount and the intake air amount of each cylinder with high responsiveness and high accuracy, as in a compression ignition internal combustion engine, the variable inter-intake cam phase mechanism 80 may be configured similarly to the variable auxiliary intake cam phase mechanism 70.

Next, a description will be given of operation of the variable intake valve actuation assembly 40 constructed as above. In the following description, the main and auxiliary intake cams 43 and 44 are described by taking the main and auxiliary intake cams 43 and 44 for the first cylinder #1 as examples. FIG. 11 is a diagram useful in explaining the cam profiles of the main and auxiliary intake cams 43 and 44, which shows an operating state of the variable intake valve actuation assembly 40 in which the auxiliary intake cam phase θmsi is set to 0 degrees by the variable auxiliary intake cam phase mechanism 70, that is, in which there is no cam phase difference between the auxiliary intake cam 44 and the main intake cam 43.

A curve indicated by a one-dot chain line in FIG. 11 represents the amount and timing of movement of a contact point where the main intake cam 43 and the intake rocker arm 51 are in contact with each other, occurring during rotation of the main intake cam 43, i.e. the amount and timing of movement of the roller 51 a, while a curve indicated by a broken line in FIG. 11 represents the amount and timing of movement of the first link 53, i.e. the pin 51 c, occurring during rotation of the auxiliary intake cam 44. The same applies to FIGS. 12B to 16, referred to hereinafter.

Further, a curve indicated by a two-dot chain line in FIG. 11 represents, for comparison, the amount and timing of movement of the adjusting bolt 51 b actuated by an intake cam (hereinafter referred to as “the Otto intake cam”) of a general engine of the Otto cycle type (Otto engine) i.e. an engine operated such that an expansion ratio and a compression ratio become equal to each other. A curve obtained by incorporating a valve clearance-related factor into the curve corresponds to a valve lift curve of an intake valve actuated by the Otto intake cam. Therefore, in the following description, this curve is referred to as “the valve lift curve” of the Otto intake cam, as required.

As shown in FIG. 11, the main intake cam 43 is configured as a so-called retarded-closing cam which, in comparison with the case of the intake valve 6 being actuated by the Otto intake cam, opens the intake valve 6 in the same lift start timing or valve-opening timing, and closes the intake valve 6 in later lift termination timing or valve-closing timing during the compression stroke. Further, the main intake cam 43 has a cam profile configured such that the maximum valve lift is continued over a predetermined range (corresponding to a cam angle of e.g. 150 degrees). In the following description, states in which the intake valve 6 is closed in later timing and in earlier timing than by the Otto intake cam are referred to as “the retarded closing” and “the advanced closing” of the intake valve 6, respectively.

Further, the auxiliary intake cam 44 has a cam profile configured such that the valve-opening timing thereof is made earlier than that of the main intake cam 43, and the maximum valve lift is continued over the above predetermined range (corresponding to a cam angle of e.g. 150 degrees).

Next, operation of the intake valve-actuating mechanism 50 performed when the intake valve 6 is actually actuated by the main and auxiliary intake cams 43 and 44 having the above cam profiles will be described with reference to FIG. 12A to FIG. 16. FIGS. 12A and 12B show an example of the operation of the intake valve-actuating mechanism 50 in which the auxiliary intake cam phase θmsi is set to 0 degrees. In FIG. 12B, a curve indicated by a solid line shows the actual amount and timing of movement of the adjusting bolt 51 b, and a curve obtained by incorporating a valve clearance-related factor corresponds to a valve lift curve indicative of the actual amount and timing of the valve lift of the intake valve 6. Therefore, in the following description, the curve indicated by the solid line is referred to as the valve lift curve of the intake valve 6, as required, and the amount and timing of movement of the adjusting bolt 51 b are referred to as the valve lift amount and the valve timing of the intake valve 6, respectively. The same also applies to FIGS. 13A to 16, referred to hereinafter.

As shown in FIG. 12A, when the auxiliary intake cam phase θmsi is set to 0 degrees, the auxiliary intake cam 44 is held in abutment with the first link 53 at a high portion of the cam nose thereof, during a time period over which the main intake cam 43 is in abutment with the intake rocker arm 51 at a high portion of the cam nose thereof. This means that during valve-opening operation by the main intake cam 43, the pivot of the pivotal motion of the intake rocker arm 51 is held at a lowermost position thereof. As a result, as shown in FIG. 12B, in the valve lift amount and the valve timing of the intake valve 6, the valve-opening timing is the same but the valve-closing timing is retarded, in comparison with the case of the intake valve 6 being actuated by the Otto intake cam. This is a state where the intake valve 6 is actuated by the retarded-closing cam.

FIG. 13A to FIG. 15B show examples of the operation of the intake valve-actuating mechanism 50 performed when the auxiliary intake cam phase θmsi is set to 90 degrees, 120 degrees, and 180 degrees, respectively, by the variable auxiliary intake cam phase mechanism 70. In other words, these figures show examples of the operation of the intake valve-actuating mechanism 50 when the phase of the auxiliary intake camshaft 42 is advanced by respective cam angles of 90 degrees, 120 degrees, and 180 degrees with respect to the main intake camshaft 41. Further, FIG. 16 shows an example of the operation of the intake valve-actuating mechanism 50 performed when the auxiliary intake cam phase θmsi is changed from 120 degrees to 180 degrees.

Referring to FIG. 13A, when the auxiliary intake cam phase θmsi is set to 90 degrees, the auxiliary intake cam 44 is held in abutment with the first link 53 not at the high portion, but at a low portion, of the cam nose thereof, during the second half of the time period over which the main intake cam 43 is in abutment with the intake rocker arm 51 at the high portion of the cam nose thereof. As a result, as shown in FIG. 13B, the valve-closing timing of the intake valve 6, i.e. termination timing of the valve-opening operation performed by the main intake cam 43 is made earlier than when the auxiliary intake cam phase θmsi is set to 0 degrees, whereby the valve timing of the intake valve 6 becomes the same as that of an intake valve actuated by the Otto intake cam.

Further, when the auxiliary intake cam phase θmsi is larger than 90 degrees, e.g. when the auxiliary intake cam phase θmsi is set to 120 degrees, as shown in FIG. 14A, during the time period over which the main intake cam 43 is in abutment with the intake rocker arm 51 at the high portion of the cam nose thereof, the time period over which the auxiliary intake cam 44 is in abutment with the first link 53 at the high portion of the cam nose thereof is made shorter than when the auxiliary intake cam phase θmsi is set to 90 degrees, which is described above. As a result, as shown in FIG. 14B, the valve-closing timing of the intake valve 6 is made still earlier than when the auxiliary intake cam phase θmsi is set to 90 degrees, and in comparison with the case of the intake valve being actuated by the Otto intake cam, the valve-opening timing is the same, but the valve-closing timing is made earlier. This is a state of the intake valve 6 being actuated by an advanced-closing cam.

Further, as shown in FIG. 16, when the auxiliary intake cam phase θmsi is changed from the above-mentioned 120 degrees to 180 degrees, during the time period over which the main intake cam 43 is in abutment with the intake rocker arm 51 at the high portion of the cam nose thereof, the time period over which the auxiliary intake cam 44 is held in abutment with the first link 53 at the high portion of the cam nose thereof is progressively reduced. As a consequence, the valve-closing timing of the intake valve 6 is progressively made earlier, and the valve lift amount of the intake valve 6 is progressively reduced from its maximum value. As described above, when the auxiliary intake cam phase θmsi is set by the variable auxiliary intake cam phase mechanism 70 such that the valve lift amount of the intake valve 6 is progressively reduced from its maximum value, it is possible to increase the flow velocity of intake air flowing into the combustion chamber to increase the fluidity of the mixture within the cylinder, thereby making it possible to enhance combustion efficiency.

Finally, when the auxiliary intake cam phase θmsi becomes equal to 180 degrees, as shown in FIG. 15A, during the time period over which the main intake cam 43 is in abutment with the intake rocker arm 51 at the high portion of the cam nose thereof, the auxiliary intake cam 44 is held in abutment with the first link 53 at the low portion of the cam nose thereof. Consequently, as shown in FIG. 15B, the amount of movement of the adjusting bolt 51 b is made very small, and the maximum value thereof is made slightly smaller than the valve clearance. As a result, when the auxiliary intake cam phase θmsi is equal to 180 degrees, the intake valve 6 is inhibited from being actuated by the adjusting bolt 51 b, whereby the intake valve 6 is held in a closed state.

Although the variable intake valve actuation assembly 40 described above is configured such that the valve lift curve of the intake valve 6 becomes the same as that of an intake valve-actuated by the Otto intake cam when the auxiliary intake cam phase θmsi is equal to 90 degrees, the value of the auxiliary intake cam phase θmsi which causes the valve lift amount to become the same as that of an intake valve actuated by the Otto intake cam can be changed as required by changing the cam profiles of the main and auxiliary intake cams 43 and 44.

Next, a description will be given of the variable exhaust valve actuation assembly 90, which is configured substantially similarly to the variable intake valve actuation assembly 40 described above, and comprised of a main exhaust camshaft 91 and an auxiliary exhaust camshaft 92, for driving the exhaust valves 7, exhaust valve-actuating mechanisms 100 (only one of which is shown in FIG. 2) provided for the respective cylinders, for opening and closing the associated exhaust valves 7 in accordance with rotation of the main and auxiliary exhaust camshafts 91 and 92, a variable main exhaust cam phase mechanism 110, a variable auxiliary exhaust cam phase mechanism 120, and three variable inter-exhaust cam phase mechanisms 130.

The main exhaust camshaft 91 includes main exhaust cams 93 provided for the respective cylinders, a main gear 95 integrally mounted thereon, and a sprocket 97 provided at one end thereof. Similarly to the sprocket 47 of the main intake camshaft 41, the sprocket 97 is connected to the crankshaft 3 b via the timing chain 48, whereby the main exhaust camshaft 91 is rotated through 360 degrees as the crankshaft 3 b rotates through 720 degrees.

The variable main exhaust cam phase mechanism 110 continuously advances or retards the relative phase of the main exhaust camshaft 91 with respect to the sprocket 97, that is, the relative phase θme of the main exhaust camshaft 91 with respect to the crankshaft 3 b (hereinafter referred to as “the main exhaust cam phase θme”). The variable main exhaust cam phase mechanism 110 is constructed similarly to the variable main intake cam phase mechanism 60, described above, and hence detailed description thereof is omitted.

Further, a main exhaust cam angle sensor 32 is disposed at the other end of the main exhaust camshaft 91, opposite to the one end where the sprocket 97 is mounted. Similarly to the main intake cam angle sensor 27, the main exhaust cam angle sensor 32 is implemented by a combination of a magnet rotor and an MRE pickup (neither of which is shown), and delivers a main exhaust cam signal, which is a pulse signal, to the ECU 2 along with rotation of the main exhaust camshaft 91. Each pulse of the main exhaust cam signal is generated whenever the main exhaust camshaft 91 rotates through a predetermined cam angle (e.g. one degree), and the ECU 2 calculates the main exhaust cam phase θme based on the main exhaust cam signal and the CRK signal.

On the other hand, the auxiliary exhaust camshaft 92 has auxiliary exhaust cams 94 mounted thereon for the respective cylinders, and an auxiliary gear 96 having the same number of gear teeth as that of gear teeth of the main gear 95. Similarly to the main and auxiliary gears 45 and 46 described above, the main and auxiliary gears 95 and 96 are both urged by urging springs, not shown, such that they are always in mesh with each other, and configured such that backlash of the meshing teeth of the main and auxiliary gears 95 and 96 is prevented from occurring by a backlash-compensating mechanism, not shown. The gears 95 and 96 are in mesh with each other, whereby as the main exhaust camshaft 91 rotates, the auxiliary exhaust camshaft 92 is rotated at the same rotational speed as that of the main exhaust camshaft 91 in a direction opposite to the direction of rotation thereof.

The variable auxiliary exhaust cam phase mechanism 120 continuously changes the relative phase of the auxiliary exhaust camshaft 92 with respect to the gear 96, in other words, the relative phase θmse of the auxiliary exhaust camshaft 92 with respect to the main exhaust camshaft 91 (hereinafter referred to as “the auxiliary exhaust cam phase θmse”). The variable auxiliary exhaust cam phase mechanism 120 is constructed similarly to the aforementioned variable auxiliary intake cam phase mechanism 70, and hence detailed description thereof is omitted.

An auxiliary exhaust cam angle sensor 33 is provided at an end of the auxiliary exhaust camshaft 92, opposite to an end thereof where the variable auxiliary exhaust cam phase mechanism 120 is provided. Similarly to the main exhaust cam angle sensor 32, the auxiliary exhaust cam angle sensor 33 is implemented by a combination of a magnet rotor and an MRE pickup (neither of which is shown), and delivers an auxiliary exhaust cam signal, which is a pulse signal, to the ECU 2 along with rotation of the auxiliary exhaust camshaft 92. Each pulse of the auxiliary exhaust cam signal is generated whenever the auxiliary exhaust camshaft 92 rotates through a predetermined cam angle (e.g. one degree). The ECU 2 calculates the auxiliary exhaust cam phase θmse based on the auxiliary exhaust cam signal, the main exhaust cam signal, and the CRK signal.

Out of the four auxiliary exhaust cams 94, the auxiliary exhaust cam 94 for the first cylinder #1 is coaxially mounted on the auxiliary exhaust camshaft 92, for rotation in unison with the auxiliary exhaust camshaft 92. While the other auxiliary exhaust cams 94 for the second to fourth cylinders #2 to #4 are connected to the auxiliary exhaust camshaft 92 via the associated variable inter-exhaust cam phase mechanisms 130, respectively. The variable inter-exhaust cam phase mechanisms 130 continuously change the relative phases (hereinafter referred to as “the inter-exhaust cam phases”) θsse#2 to θsse#4 of the auxiliary exhaust cams 94 for the second to fourth cylinders #2 to #4, respectively, with respect to the auxiliary exhaust cam 94 for the first cylinder #1, independently of each other. The variable inter-exhaust cam phase mechanisms 130 are constructed similarly to the variable inter-intake cam phase mechanisms 80, and hence detailed description thereof is omitted.

Further, although not shown, three #2 to #4 auxiliary exhaust cam angle sensors constructed similarly to the above #2 to #4 auxiliary intake cam angle sensors 29 to 31 are electrically connected to the ECU 2. The #2 to #4 auxiliary exhaust cam angle sensors deliver respective #2 to #4 auxiliary exhaust cam signals, which are pulse signals, to the ECU 2 along with rotation of the auxiliary exhaust cams 94 for the second to fourth cylinders #2 to #4. Each pulse of the auxiliary exhaust cam signals is generated whenever the associated auxiliary exhaust cam 94 rotates through a predetermined cam angle (e.g. one degree). The ECU 2 calculates the inter-exhaust cam phases θsse#2 to θsse#4 based on the respective #2 to #4 auxiliary exhaust cam signals, the auxiliary exhaust cam signal, the main exhaust cam signal, and the CRK signal.

Each exhaust valve-actuating mechanism 100 is constructed similarly to the intake valve-actuating mechanism 50, and comprised of the associated main and auxiliary exhaust cams 93 and 94, an exhaust rocker arm 101 for opening and closing the associated exhaust valve 7, and a link mechanism 102 supporting the exhaust rocker arm 101. The main and auxiliary exhaust cams 93 and 94 have the same cam profiles as those of the main and auxiliary intake cams 43 and 44, respectively. Further, since the exhaust rocker arm 101 and the link mechanism 102 are constructed similarly to the intake rocker arm 51 and the link mechanism 52, respectively, detailed description thereof is omitted, but the exhaust rocker arm 101 has an adjusting bolt 101 b similar to the adjusting bolt 51 b, mounted at an end thereof opposite to an end where the main exhaust cam 93 is mounted, and is pivotally supported by a first link 103.

Next, a description will be given of operation of the variable exhaust valve actuation assembly 90 constructed as above. In the following description, the main and auxiliary exhaust cams 93 and 94 are described by taking the main and auxiliary exhaust cams 93 and 94 for the first cylinder #1 as examples. FIG. 17 is a diagram useful in explaining the cam profiles of the main and auxiliary exhaust cams 93 and 94, which shows an example of the operation of the variable exhaust valve actuation assembly 90 performed when the auxiliary exhaust cam phase θmse is set to 0 degrees by the variable auxiliary exhaust cam phase mechanism 120.

A curve indicated by a one-dot chain line in FIG. 17 represents the amount and timing of movement of a contact point where the main exhaust cam 93 and the exhaust rocker arm 101 are in contact with each other, occurring during rotation of the main exhaust cam 93, while a curve indicated by a broken line in FIG. 17 represents the amount and timing of movement of the first link 103, occurring during rotation of the auxiliary exhaust cam 94. The same applies to FIGS. 18 to 21, referred to hereinafter.

Further, a curve indicated by a two-dot chain line in FIG. 17 represents, for comparison, the amount and timing of movement of the adjusting bolt 101 b actuated by an exhaust cam (hereinafter referred to as “the Otto exhaust cam”) of the general engine of the Otto cycle type (Otto engine). A curve obtained by incorporating a valve clearance-related factor into the curve corresponds to a valve lift curve of an exhaust valve actuated by the Otto exhaust cam. Therefore, in the following description, this curve is referred to as “the valve lift curve” of the Otto exhaust cam, as required.

As shown in FIG. 17, the main exhaust cam 93 is configured as a so-called advanced-opening cam, which in comparison with the Otto exhaust cam, close the exhaust valve 7 in the same valve-closing timing, and opens the same in earlier timing during the expansion stroke. Further, the main exhaust cam 93 has a cam profile configured such that the maximum valve lift is continued over a predetermined range (corresponding to a cam angle of e.g. 90 degrees). In the following description, states in which the exhaust valve 7 is opened in later timing and in earlier timing than by the Otto exhaust cam are referred to as “the retarded opening” and “the advanced opening” of the exhaust valve 7, respectively.

Further, compared with the main exhaust cam 93, the auxiliary exhaust cam 94 has a cam profile configured such that the exhaust valve 7 is made open for a longer time period and the maximum valve lift is continued over a predetermined longer range (corresponding to a cam angle of e.g. 150 degrees).

Next, operation of the exhaust valve-actuating mechanism 100 performed when the exhaust valve 7 is actually actuated by the main and auxiliary exhaust cams 93 and 94 having the above cam profiles will be described with reference to FIGS. 18 to 21. FIG. 18 shows an example of the operation of the exhaust valve-actuating mechanism 100 in which the auxiliary exhaust cam phase θmse is set to 0 degrees. It should be noted that a curve indicated by a solid line in FIG. 18 shows the actual amount and timing of movement of the adjusting bolt 101 b and, as described above, substantially corresponds to the valve lift curve of the exhaust valve 7. Therefore, in the following description, the curve indicated by the solid line is referred to as the valve lift curve of the exhaust valve 7 as required, and the actual amount and timing of movement of the adjusting bolt 101 b are referred to as the valve lift amount and the valve timing of the exhaust valve 7, respectively. The same applies to FIGS. 19 to 21, referred to hereinafter.

When the auxiliary exhaust cam phase θmse is equal to 0 degrees, the auxiliary exhaust cam 94 is held in abutment with the first link 103 at a low portion of a cam nose thereof, during a time period over which the main exhaust cam 93 is in abutment with the exhaust rocker arm 101 at a high portion of a cam nose thereof. As a result, as shown in FIG. 18, the amount of movement of the adjusting bolt 101 b is made very small, and the maximum value thereof is made slightly smaller than the valve clearance. Therefore, when the auxiliary exhaust cam phase θmse is equal to 0 degrees, the exhaust valve 7 is inhibited from being actuated by the adjusting bolt 101 b, whereby the exhaust valve 7 is held in a closed state.

FIGS. 19 to 21 show examples of operation of the exhaust valve 7 performed when the auxiliary exhaust cam phase θmse is set to 45 degrees, 90 degrees, and 150 degrees, respectively, by the variable auxiliary exhaust cam phase mechanism 120. In other words, these figures show examples of operation of the variable main exhaust cam phase mechanism 110 performed when the phase of the auxiliary exhaust camshaft 92 is advanced by respective amounts corresponding to cam angles of 45 degrees, 90 degrees, and 150 degrees, with respect to the main exhaust camshaft 91.

With the arrangement of the exhaust valve-actuating mechanisms 100 described above, as the auxiliary exhaust cam phase θmse is increased, in other words, as the phase of the auxiliary exhaust camshaft 92 is advanced with respect to the main exhaust camshaft 91, a time period over which the auxiliary exhaust cam 94 is held in abutment with the first link 103 at a high portion of the cam nose thereof is made longer, during the time period over which the main exhaust cam 93 is in abutment with the exhaust rocker arm 101 at the high portion of the cam nose thereof. As a result, as shown in FIGS. 19 to 21, as the auxiliary exhaust cam phase θmse is increased, the valve-opening timing of the exhaust valve 7 is made earlier.

More specifically, in the FIG. 19 example in which the auxiliary exhaust cam phase θmse is equal to 45 degrees, the exhaust valve 7 is in a state actuated by a retarded-opening cam, in which in comparison with the case of the exhaust valve 7 being actuated by the Otto exhaust cam, the valve-closing timing is the same, and the valve-opening timing is made earlier. Further, in the FIG. 20 example in which the auxiliary exhaust cam phase θmse is set to 90 degrees (=θmseott), the valve timing of the exhaust valve 7 is the same as that of an exhaust valve actuated by the Otto exhaust cam. Further, when the auxiliary exhaust cam phase θmse is larger than 90 degrees, e.g. when the auxiliary exhaust cam phase θmse is equal to 150 degrees, as shown in FIG. 21, the exhaust valve 7 is in a state actuated by an advanced-closing cam, in which in comparison with the case of the exhaust valve 7 being actuated by the Otto exhaust cam, the valve-closing timing is the same, and the valve-opening timing is made earlier. Although not shown, the exhaust valve-actuating mechanisms 100 is configured such that in the range of the auxiliary exhaust cam phase θmse from 0 to 60 degrees, the amount of the valve lift of the exhaust valve 7 is increased as the auxiliary exhaust cam phase θmse is increased.

Now, as shown in FIG. 3, connected to the ECU 2 are an intake pipe temperature sensor 34, an accelerator opening sensor 35, and an ignition switch (hereinafter referred to as “the IG·SW”) 36. The intake pipe temperature sensor 34 detects air temperature TB in the intake pipe 8, and delivers a signal indicative of the sensed air temperature TB to the ECU 2. The accelerator pedal opening sensor 35 detects a stepped-on amount (hereinafter referred to as “the accelerator pedal opening”) AP of an accelerator pedal, not shown, of the vehicle and delivers a signal indicative of the sensed accelerator pedal opening AP to the ECU 12. Further, the IG SW 36 is turned on or off by operation of an ignition key, not shown, and delivers a signal indicative of the ON/OFF state thereof to the ECU 2.

Next, the ECU 2 will be described. The ECU 2 is implemented by a microcomputer including an I/O interface, a CPU, a RAM, and a ROM, none of which are shown. The ECU 2 determines operating conditions of the engine 3, based on the signals delivered from the above-mentioned sensors 20 to 35 and the IG-SW 36. Further, the ECU 2 executes control processes, which will be described in detail hereinafter, according to control programs read from the ROM, using data stored in the RAM, and the like.

It should be noted that in the present embodiment, the ECU 2 forms estimated intake air amount-calculating means, target intake air amount-setting means, identification means, control command value-calculating means, control means, estimated value-calculating means, output-detecting means, target value-setting means, prediction means, control command value-determining means, and cylinder intake air amount-detecting means.

Referring to FIG. 22, the control system 1 according to the present embodiment includes a DUTY_th-calculating section 200, a Gcyl-calculating section 210, an auxiliary intake cam phase controller 220, and an inter-intake cam phase controller 230, all of which are implemented by the ECU 2. In the DUTY_th-calculating section 200, as described hereinafter, a target opening degree TH_cmd, which is a target value of the throttle valve opening TH, is calculated according to a target intake air amount Gcyl_cmd, and further the control input DUTY_th to the throttle valve mechanism 16 is calculated based on the target opening degree TH_cmd.

The Gcyl-calculating section 210 calculates a cylinder intake air amount Gcyl (estimated intake air amount) of intake air estimated to have been drawn into a cylinder, by an equation (1) shown in FIG. 24. In this equation (1), the symbols VB, R, and TB represent the volume of the inside of the intake pipe 8, a predetermined gas constant, and temperature within the intake pipe 8, respectively. Further, the symbol n represents a discretized time, and indicates that each discrete data (time-series data) with (n), (n−1), or the like is data sampled at a predetermined repetition period (e.g. synchronous with input of the TDC signal, or set to a fixed time period). Further, the data with (n) indicates that it has a current value, and the data with (n−1) indicates that it has an immediately preceding value. This also applies to discrete data referred to hereinafter. Furthermore, in the description throughout the specification, the symbols (n), (n−1), and so forth indicating that data therewith are discrete data will be omitted as appropriate.

The auxiliary intake cam phase controller 220 calculates a control input DUTY_msi to the variable auxiliary intake cam phase mechanism 70, according to the cylinder intake air amount Gcyl calculated by the Gcyl-calculating section 210 and so forth. Details of the auxiliary intake cam phase controller 220 will be described hereinafter.

Further, the inter-intake cam phase controller 230 calculates respective control inputs DUTY_ssi#2 to DUTY_ssi#4 to the three variable inter-intake cam phase mechanisms 80, as will be described hereinafter, so as to correct the variation in intake air amount between the cylinders. Details of the inter-intake cam phase controller 230 will be described hereinafter.

Next, a description will be given of the auxiliary intake cam phase controller 220. As shown in FIG. 23, the auxiliary intake cam phase controller 220 is comprised of a first SPAS controller 221 that calculates a target auxiliary intake cam phase θmsi_cmd (control command value), and a second SPAS controller 225 that calculates the control input DUTY_msi.

The first SPAS controller 221 calculates the target auxiliary intake cam phase θmsi_cmd with a self-tuning prediction pole assignment control algorithm, referred to hereinafter, based on the cylinder intake air amount Gcyl, the target intake air amount Gcyl_cmd, and a demanded drive torque TRQ_eng. The first SPAS controller 221 is comprised of a state predictor 222, an onboard identifier 223, and a sliding mode controller 224.

First, the state predictor 222 (predicted value-calculating means) will be described. With a prediction algorithm, described hereinafter, the state predictor 222, predicts (calculates) a predicted intake air amount Pre_Gcyl (predicted value of the output from the plant), which is a predicted value of the cylinder intake air amount Gcyl.

First, when a controlled object to which is inputted the target auxiliary intake cam phase θmsi and from which is outputted the cylinder intake air amount Gcyl is modeled as an ARX model (auto-regressive model with exogenous input) which is a discrete-time system model, an equation (2) shown in FIG. 24 can be obtained. In this equation (2), the symbol d represents dead time determined depending on the characteristics of the controlled object. Further, the symbols a1, a2, and b1 represent model parameters, which are sequentially identified by the onboard identifier 223, as described hereinafter.

Then, when the equation (2) is shifted toward the future side by the amount of discrete time [d−1], an equation (3) in FIG. 24 can be obtained. Further, when matrices A and B are defined by equations (4) and (5) in FIG. 24 using the model parameters a1, a2, and b1, and the equation (3) is changed by repeatedly using a recurrence formula thereof to eliminate future values [Gcyl(n+d−2), Gcyl(n+d−3)) on the left side of the equation (3), an equation (6) shown in FIG. 24 can be obtained.

Although it is possible to calculate the predicted intake air amount Pre_Gcyl using the equation (6), shortage of the order of the model, a nonlinear characteristic of the controlled object, and so forth can cause a steady-state deviation and modeling errors in the predicted intake air amount Pre_Gcyl.

To avoid this problem, the state predictor 222 according to the present embodiment calculates the predicted intake air amount Pre_Gcyl using an equation (7) shown in FIG. 24 in place of the equation (6). This equation (7) can be obtained by adding to the right side of the equation (6), a compensation parameter γ1 for compensating for a steady-state deviation between the predicted intake air amount Pre_Gcyl and the cylinder intake air amount Gcyl, caused by a modeling error and a nonlinear characteristic of the controlled object. The compensation parameter γ1 is set as an addition term (or a subtraction term).

Next, a description will be given of the onboard identifier 223 (identification means). With a sequential identification algorithm, described hereinbelow, the onboard identifier 223 identifies a predictive coefficient vector θs which is a vector of matrix components α1, α2, and βj of model parameters, and the compensation parameter γ1, in the aforementioned equation (7), such that an identification error ide, which is the difference between the predicted intake air amount Pre_Gcyl and the cylinder intake air amount Gcyl, is minimized (i.e. such that the predicted intake air amount Pre_Gcyl matches the cylinder intake air amount Gcyl as much as possible).

More specifically, a predictive coefficient vector θs(n) is calculated using equations (8) to (13) shown in FIG. 25. The transposed matrix of the predictive coefficient vector θs(n) is defined by an equation (12) shown in FIG. 25. Further, in the equation (8), the symbol KPs(n) represents a vector of a gain coefficient, and the gain coefficient KPs(n) is calculated by the equation (9). In the equation (9), the symbol Ps(n) represents a square matrix of order (d+2) defined by the equation (10), and the symbol ζ s(n) represents a vector whose transposed matrix is defined by the equation (13). Further, an identification error ide(n) in the equation (8) is calculated by the equation (11).

In the identification algorithm as described above, by setting the weighting parameters λ1 and λ2 in the equation (10), one of the following identification algorithms is selected:

λ1=1, λ2=0: fixed gain algorithm;

λ1=1, λ2=1: least-squares method algorithm;

λ1=1, λ2=λ: progressively decreasing gain algorithm; and

λ1=λ, λ2=1: weighted least-squares method algorithm,

wherein λ is a predetermined value set such that 0<λ<1 holds.

It should be noted that in the present embodiment, the weighted least-squares method is employed so as to optimally secure both identification accuracy and a convergence rate at which the vector θs converges to an optimal value.

Next, a description will be given of the sliding mode controller (hereinafter referred to as “the SLD controller”) 224. The SLD controller 224 (control command value-determining means, control command value-calculating means) calculates the target auxiliary intake cam phase θmsi_cmd based on a sliding mode control algorithm, such that the cylinder intake air amount Gcyl converges to the target intake air amount Gcyl_cmd (target value of the output from the plant, or target value of the cylinder intake air amount), and at the same time the auxiliary intake cam phase θmsi is constrained to a basic value θmsi_base. In the following, a description will be given of the sliding mode control algorithm.

First, in the sliding mode control algorithm, an equation (14) shown in FIG. 26 is used as a controlled object model. This equation (14) is obtained by shifting the above-mentioned equation (6) in FIG. 24 toward the future side by the amount of discrete time [1].

When the controlled object model expressed by the equation (14) is used, a switching function as is set as follows: As expressed by an equation (15) in FIG. 26, when a following error Es is defined as the difference between the cylinder intake air amount Gcyl and the target intake air amount Gcyl_cmd, the switching function σs is set as a linear function of the time series data (discrete data) of the following error Es, as expressed by an equation (16) in FIG. 26. It should be noted that the symbol Ss used in the equation (16) represents a switching function-setting parameter.

In the sliding mode control algorithm, when the switching function as is formed by two state variables [Es(n), Es(n−1)] as in the present embodiment, as shown in FIG. 28, a phase space formed by the two state variables is a two-dimensional phase plane having the longitudinal axis and the horizontal axis respectively defined by the state variables, and on the phase plane, a combination of two values of the state variables satisfying the condition of σs=0 is on a straight line referred to as a switching line, which is expressed by a mathematical expression [Es(n)=−Ss·Es(n−1)].

The above mathematical expression [Es(n)=−Ss·Es(n−1)] expresses a first-order lag system with no input. Therefore, if the switching function-setting parameter Ss is set such that −1<Ss<1 holds, for example, and at the same time the first-order lag system is stabilized, the combination of the two state variables [Es(n), Es(n−1)] converges to an equilibrium point at which the two values each become equal to a value of 0, with the lapse of time. More specifically, by thus causing the following error Es to converge to a value of 0, it is possible to cause the cylinder intake air amount Gcyl to converge (slide) to the target intake air amount Gcyl_cmd. It should be noted that asymptotic approach of the two values of the state variables [Es(n), Es(n−1)] to the switching line is referred to as “the reaching mode”, and a sliding behavior of the two values to the equilibrium point is referred to as “the sliding mode”.

In this case, when the switching function-setting parameter Ss is set to a positive value, the first-order lag system expressed by the equation [Es(n)=−Ss·Es(n−1)] becomes an oscillating-stability system, which is not preferable for the converging behavior of the state variables [Es(n), Es(n−1)]. Therefore, in the present embodiment, the switching function-setting parameter Ss is set as expressed by an equation (17) in FIG. 26. When the switching function-setting parameter Ss is set as above, as shown in FIG. 29, as the absolute value of the switching function-setting parameter Ss is smaller, a convergence rate at which the following error Es converges to a value of 0, that is, a convergence rate at which the cylinder intake air amount Gcyl converges to the target intake air amount Gcyl_cmd is higher. As described hereinabove, in the sliding mode control, the switching function-setting parameter Ss makes it possible to specify as desired the converging behavior and convergence rate of the cylinder intake air amount Gcyl which should be caused to converge to the target intake air amount Gcyl_cmd.

Further, as expressed by an equation (18) in FIG. 26, a control input Uspas(n) [=θmsi_cmd(n)] for placing the combination of the state variables [Es(n), Es(n-1)] on the switching line is defined as the sum total of an equivalent control input Ueq(n), a reaching law input Urch(n), and a valve control input Uvt(n) as command value components.

The equivalent control input Ueq(n) is for constraining the combination of [Es(n), Es(n−1)] on the switching straight line, and specifically, it is defined by an equation (19) shown in FIG. 26. The equation (19) is derived as follows: When an equation (22) shown in FIG. 27 is changed based on the equation (16) described above, an equation (23) shown in FIG. 27 can be obtained. Then, when the equation (23) is changed by repeatedly using a recurrence formula thereof, an equation (24) shown in FIG. 27 can be obtained. Further, when the terms of the auxiliary intake cam phase θmsi in the equation (24) are collectively changed, an equation (25) shown in FIG. 27 can be obtained. Subsequently, in the equation (25), an auxiliary intake cam phase θmsi(n) on the left side thereof is replaced by the equivalent control input Ueq(n), and at the same time a future value Gcyl(n+d−1) and the like of the cylinder intake air amount on the right side thereof are replaced by the predicted value Pre_Gcyl based on the relationship of Pre_Gcyl(n) Gcyl(n+d−1) described hereinabove, whereby the equation (19) is derived.

The reaching law input Urch(n) is for causing the combination of [Es(n), Es(n−1)] to converge onto the switching straight line when the combination has deviated from the switching straight line due to disturbance or a modeling error, and specifically, defined by an equation (20) shown in FIG. 26.

Further, the valve control input Uvt(n) as a selection command value component is a feedforward input for constraining the auxiliary intake cam phase θmsi to the basic value θmsi_base thereof. More specifically, it is defined as a value equal to the basic value θmsi_base, as expressed by an equation (21) in FIG. 26. It should be noted that basic value θmsi_base is calculated according to the demanded drive torque TRQ_eng, as will be described hereinafter.

As described above, in the first SPAS controller 221, the state predictor 222 calculates the predicted intake air amount Pre_Gcyl with the state prediction algorithm having the compensation parameter γ1 added thereto, and the onboard identifier 223 sequentially identifies the compensation parameter γ1, so that it is possible to accurately match the dynamic characteristics of the predicted intake air amount Pre Gcyl with those of the cylinder intake air amount Gcyl. This make it possible to calculate the predicted intake air amount Pre_Gcyl with accuracy, while compensating for the steady-state deviation between the predicted intake air amount Pre_Gcyl and the cylinder intake air amount Gcyl.

Further, the SLD controller 224 calculates the target auxiliary intake cam phase θmsi_cmd as the sum total of the reaching law input Urch, the equivalent control input Ueq, and the valve control input Uvt, which makes it possible to cause the following error converge Es to converge to a value of 0 by the reaching law input Urch and the equivalent control input Ueq. That is, it is possible to cause the cylinder intake air amount Gcyl to converge to the target intake air amount Gcyl_cmd, and at the same time specify the converging behavior and convergence rate thereof as desired by configuration of the switching function-setting parameter Ss. This makes it possible to set the convergence rate at which the cylinder intake air amount Gcyl converges to the target intake air amount Gcyl_cmd, to an appropriate value dependent on the characteristics of the controlled object (intake system including the variable auxiliary intake cam phase mechanism 70 and the like), to thereby cause the cylinder intake air amount Gcyl to quickly and stably converge to the target intake air amount Gcyl_cmd, while preventing oscillatory and overshooting behaviors. Thus, the controllability of the present system can be enhanced.

Further, the valve control input Uvt makes it possible to constrain the auxiliary intake cam phase θmsi to the basic value θmsi_base thereof, and even when there are two solutions to the target auxiliary intake cam phase θmsi_cmd, one on the retarded-closing side and the other on the advanced-closing side, the valve control input Uvt makes it possible to forcibly select one of the two solutions as a solution to the target auxiliary intake cam phase θmsi_cmd. Besides, since the compensation parameter γ1 is included in the predictive coefficient vector θs identified by the onboard identifier 223, it is possible to properly converge the cylinder intake air amount Gcyl to the target intake air amount Gcyl_cmd, while compensating for influence of the valve control input Uvt.

Next, a description will be given of the second SPAS controller 225 (control means) mentioned above. The second SPAS controller 225 calculates the control input DUTY_msi according to the auxiliary intake cam phase θmsi and the target auxiliary intake cam phase θmsi_cmd with a control algorithm similar to the control algorithm of the first SPAS controller 221 except for part thereof, and as shown in FIG. 30, the second SPAS controller 225 is comprised of a state predictor 226, an onboard identifier 227, and a sliding mode controller 228.

With the same prediction algorithm as that of the state predictor 222, the state predictor 226 predicts (calculates) a predicted auxiliary intake cam phase Pre_θmsi, which is a predicted value of the auxiliary intake cam phase θmsi.

More specifically, an equation (26) shown in FIG. 31 is used as a controlled object model. In the equation (26), the symbol dx represents dead time determined depending on characteristics of a controlled object, and the symbols a1′, a2′, and b1′ represent model parameters. Further, the symbol m represents a discretized time, and indicates that each discrete data with a symbol (m) or the like is data sampled at a predetermined repetition period shorter than the sampling period for sampling the discrete data with the symbol (n) described hereinbefore. This also applies to discrete data referred to hereinafter. In the description of the present specification, the symbol (m) and like other symbols indicating that data therewith are discrete data will be omitted as appropriate. It should be noted that the reason why the sampling period for sampling each discrete data in the equation (26) is set to a period shorter than the sampling period for sampling each discrete data in the equation (2) described above is as follows: If the convergence rate at which the second SPAS controller 225 causes the auxiliary intake cam phase θmsi to converge to the target auxiliary intake cam phase θmsi_cmd is lower than the convergence rate at which the first SPAS controller 221 causes the cylinder intake air amount Gcyl to converge to the target intake air amount Gcyl_cmd, the controllability of the system is degraded, and hence the sampling period for sampling each discrete data in the equation (26) is made shorter with a view to avoiding the degradation and ensuring excellent controllability of the system.

When matrices A′ and B′ are defined by equations (27) and (28) shown in FIG. 31 using the model parameters a1′, a2′, and b1′, and the equation (26) is changed similarly to the case of the state predictor 222 described above, an equation (29) shown in FIG. 31 is derived. In the equation (29), the symbol γ′ represents a compensation parameter for compensating for a steady-state deviation and a modeling error, similarly to the compensation parameter γ1.

Further, the onboard identifier 227 as well identifies, with a sequential identification algorithm similar to that of the onboard identifier 223, a vector θs′ of matrix components α1′, α2′, and βj′ of model parameters, and the compensation parameter γ1′, in the above equation (29), such that an identification error ide′, which is the difference between the predicted auxiliary intake come phase Pre_θmsi and the auxiliary intake come phase θmsi, is minimized (i.e. such that the predicted auxiliary intake come phase Pre_θmsi becomes equal to the auxiliary intake come phase θmsi).

More specifically, a vector θs′(m) is calculated by equations (30) to (35) shown in FIG. 32. These equations (30) to (35) are configured similarly to the equations (8) to (13) described above, and hence description thereof is omitted.

Next, a description will be given of the sliding mode controller (hereinafter referred to as “the SLD controller”) 228. The SLD controller 228 calculates the control input DUTY_msi based on a sliding mode control algorithm, such that the auxiliary intake cam phase θmsi converges to the target auxiliary intake cam phase θmsi_cmd.

More specifically, the control input DUTY_msi is calculated with an algorithm expressed by equations (36) to (41) in FIG. 33. That is, when a following error Es′ is defined as the difference between the auxiliary intake cam phase θmsi and the target auxiliary intake cam phase θmsi_cmd, as expressed by the equation (36) in FIG. 33, a switching function σs′ and a switching function-setting parameter Ss' are defined by the equations (37) and (38), respectively. Further, as expressed by the equation (39) in FIG. 33, the control input DUTY_msi is defined as the sum total of an equivalent control input Ueq′ and a reaching law input Urch′. The equivalent control input Ueq′ and the reaching law input Urch′ are defined by the equations (40) and (41), respectively. As expressed by the equation (39), the SLD controller 228 is only required to control the auxiliary intake cam phase θmsi such that it converges to the target auxiliary intake cam phase θmsi_cmd, and hence the valve control input Uvt referred to hereinabove is omitted from input components of the control input DUTY_msi.

As described above, in the second SPAS controller 225 as well, the state predictor 226 calculates the predicted auxiliary intake come phase Pre_(—0) msi with the state prediction algorithm having the compensation parameter γ1′ added thereto, and the onboard identifier 227 sequentially identifies the compensation parameter γ1′, so that it is possible to accurately calculate the predicted auxiliary intake come phase Pre_θmsi, while compensating for the steady-state deviation and the modeling error.

Further, with the reaching law input Urch′ and the equivalent control input Ueq′, the SLD controller 227 is capable of causing the auxiliary intake cam phase θmsi to converge to the target auxiliary intake cam phase θmsi_cmd, and at the same time capable of specifying the converging behavior and convergence rate of the auxiliary intake cam phase θmsi as desired by configuration of the switching function-setting parameter Ss′. As a result, the convergence rate at which the auxiliary intake cam phase θmsi converges to the target auxiliary intake cam phase θmsi_cmd can be set to an appropriate value dependent on the characteristics of a controlled object (system including the variable auxiliary intake cam phase mechanism 70), to thereby enhance the controllability of the system.

It should be noted that when the values of the above two switching function-setting parameters Ss and Ss′ are set such that they have a relationship of 1<Ss<Ss′<0, the response of the control by the second SPAS controller 225 can be enhanced in comparison with that of control by the first SPAS controller 221, thereby making it possible to improve the controllability of the auxiliary intake cam phase controller 220, i.e. the convergence of the cylinder intake air amount Gcyl to the target intake air amount Gcyl_cmd.

Next, a description will be given of the inter-intake cam phase controller 230. As shown in FIG. 34, when the TH passing intake air amount Gth is detected by the air flow sensor 21, pulsation of the intake air caused by the air intake behavior of each cylinder is also detected. When there occurs variation in intake air amount between the cylinders, the pulsation of the intake air becomes irregular as shown in FIG. 34. That is, FIG. 34 shows a case in which the TH passing intake air amount Gth in the fourth cylinder #4 is smaller than those of the other cylinders.

The inter-intake cam phase controller 230 estimates the variation in intake air amount between the cylinders, and for elimination of the variation, calculates respective control inputs DUTY_ssi#2 to DUTY_ssi#4 to the three variable inter-intake cam phase mechanisms 80. The inter-intake cam phase controller 230 is comprised of an adaptive observer 240, three differentiators 250, and an intake air variation controller 260 (see FIG. 22). In the inter-intake cam phase controller 230, with an algorithm described hereinbelow, the adaptive observer 240 calculates four intake air amount variation coefficients 4#1 to (#4 on a cylinder-by-cylinder basis; the three differentiators 250 calculate three differences EΦ#2 to EΦ#4, respectively; and further the intake air variation controller 260 calculates three control inputs DUTY_ssi#2 to DUTY_ssi#4.

Next, a description will be given of the algorithm of the adaptive observer 240. First, as shown in FIG. 35, the intake system of the engine 3 is regarded as a system which is represented by four simulated values Gcyl_OS#1 to Gcyl_OS#4, and four intake air amount variation coefficients Φ#1 to Φ#4. These simulated values Gcyl_OS#i (i=1 to 4) are values simulating the intake start timing of intake air and the air intake behavior, on a cylinder-by-cylinder basis, and the intake air amount variation coefficient Φ#i (i=1 to 4) represents the variation in intake air amount between the cylinders and the amount of change in the air intake behavior. When this system is modeled into a discrete-time system model, there is obtained an equation (42) shown in FIG. 36.

In the equation (42), the symbol k represents a discretized time, and indicates that each discrete data with the symbol (k) is data sampled whenever a pulse of the TDC signal is generated (each discrete data may be data sampled whenever a pulse of the CRK signal is generated.) Further, the symbol d′ represents dead time which the air takes to flow through the intake pipe 8 from the air flow sensor 21 to each cylinder, and is set to a predetermined fixed value in the present embodiment. The dead time d′ may be set depending on operating conditions (e.g. the engine speed NE and the like) of the engine 3.

In the adaptive observer 240 according to the present embodiment, an equation formed by replacing the left side of the equation (42) by an estimated value Gth_est(k) of the TH passing intake air amount, i.e. an equation (43) in FIG. 36, is used as a model, and a signal generator 241 generates the simulated value Gcyl_OS#i, as described hereinafter. At the same time, a vector φ(k) of the intake air amount variation coefficient Φ#i as a model parameter of the equation (43) is identified by the sequential least-squares method expressed by equations (44) to (50) in FIG. 36 such that the estimated value Gth_est(k) becomes equal to the TH passing intake air amount Gth(k−d′).

The transposed matrix of the above vector φ(k) is defined by the equation (49) in FIG. 36. Further, in the equation (44), the symbol KR(k) represents the vector of a gain coefficient, and this gain coefficient KR(k) is calculated by the equation (45). In the equation (45), the symbol R(k) represents a square matrix of order 4 defined by the equation (48), and the symbol ζ′(k) represents a vector whose transposed matrix is defined by the equation (50). Furthermore, the symbol ide′(k) in the equation (44) represents an identification error. This identification error ide′(k) is calculated by the equations (46) and (47).

As described above, the adaptive observer 240 identifies the vector φ(k) of the intake air amount variation coefficient Φ#i with the algorithm based on the sequential least-squares method expressed by the equations (44) to (50). This makes it possible to remove (filter off) noise-like fluctuating components of the air intake behavior caused e.g. by a sudden change in the operating condition of the engine 3 from the intake air amount variation coefficient Φ#i, and thereby calculate the intake air amount variation coefficient Φ#i as a value substantially indicative of the variation in intake air amount between the cylinders.

The configuration of the adaptive observer 240 is represented by a block diagram shown in FIG. 37. That is, as shown in FIG. 37, in the adaptive observer 240, the signal generator 241 generates the vector ζ′(k) of the simulated values Gcyl_OS#i. More specifically, as shown in FIG. 38, the signal generator 241 generates the simulated values Gcyl_OS#i as signal values each having a waveform of a combination of alternating waves, such as triangular and trapezoidal waves, formed such that the sum total of the simulated values constantly becomes equal to a value of 1. Further, a multiplier 242 generates the estimated value Gth_est(k) of the TH passing intake air amount as a value obtained by multiplying the vector ζ′(k) of the simulated values by the vector φ(k−1) of the intake air amount variation coefficient, obtained by delaying the vector φ(k) using a delay element 243. Then, a differentiator 244 generates the identification error ide′(k) as the difference between the TH passing intake air amount Gth(k−d′) obtained by delaying the TH passing intake air amount Gth(k) using a delay element 245, and the estimated value Gth_est(k).

Further, a logic unit 246 generates the vector KR(k) of the gain coefficient based on the vector ζ′(k) of the simulated values, and a multiplier 247 generates the product [ide′(k)·KP(k)] of the identification error ide′(k) and the vector KP(k) of the gain coefficient. Then, an adder 248 generates the vector φ(k) of the intake air amount variation coefficient as the sum of the product [ide′(k)·KP(k)] and the vector φ(k−1) of the intake air amount variation coefficient, obtained by delaying the vector φ(k) using the delay element 243.

As described above, the adaptive observer 240 calculates the four intake air amount variation coefficients Φ#1 to Φ#4, and the aforementioned three differentiators 250 calculate the three differences EΦ#2 to EΦ#4, respectively, based on the intake air amount variation coefficients Φ#1 to Φ#4, by an equation (51) in FIG. 39.

Next, a description will be given of the intake air variation controller 260. Referring to FIG. 40, the intake air variation controller 260 is comprised of a target inter-intake cam phase controller 261, and a third SPAS controller 262. The target inter-intake cam phase controller 261 calculates a target inter-intake cam phase θssi#i_cmd so as to eliminate variation in the TH passing intake air amount Gth between the cylinders.

More specifically, the target inter-intake cam phase θssi#i_cmd is calculated based on the three differences EΦ#2 to EΦ#4 with a response-specifying (or pole assignment) control algorithm (sliding mode control algorithm or back-stepping control algorithm) expressed by equations (52) and (53) in FIG. 39. It should be noted that the symbol σ′(k) in the equation (52) represents a switching function. The target inter-intake cam phase controller 261 calculates target inter-intake cam phase θssi#i_cmd (#i=2 to 4) with the response-specifying control algorithm such that EΦ#i (#i=2 to 4) become equal to a value of 0. In other words, the target inter-intake cam phase θssi#i_cmd is calculated such that each of the intake air amount variation coefficients Φ#2 to Φ#4 of the second to fourth cylinders #2 to #4 becomes equal to the intake air amount variation coefficient Φ#1 of the first cylinder #1.

Further, the third SPAS controller 262 calculates the control input DUTY_ssi#i to each variable inter-intake cam phase mechanism 80 such that the inter-intake cam phase θssi#i converges to the target inter-intake cam phase θssi#i_cmd calculated as above. To be more specific, the control input DUTY_ssi#i is calculated with the same algorithm as the control algorithm of the second SPAS controller 225 described above, and hence description thereof is omitted.

As described above, the inter-intake cam phase controller 230 calculates the target inter-intake cam phase θssi#i_cmd such that the intake air amount variation coefficients Φ#2 to Φ#4 of the second to fourth cylinders #2 to #4 become equal to the intake air amount variation coefficient Φ#1 of the first cylinder #1. Further, the controller 230 calculates the control input DUTY_ssi#i such that the inter-intake cam phase θssi#i converges to the target inter-intake cam phase θssi#i_cmd. In other words, the inter-intake cam phase controller 230 controls the respective intake air amounts of the second to fourth cylinders #2 to #4 such that they become equal to the intake air amount of the first cylinder #1, thereby making it possible to eliminate the variation in intake air amount between the cylinders.

It should be noted that as shown in FIG. 34, even when the intake pipe absolute pressure PBA is detected by the intake pipe absolute pressure sensor 24, it is possible to detect the pulsation of intake air, so that with an algorithm in which the parameter represented by the intake air amount “Gth” in the above equations (42) to (53) is replaced by a parameter represented by the intake pipe absolute pressure “PBA”, and using the intake pipe absolute pressure PBA detected by the intake pipe absolute pressure sensor 24, it is possible to form the inter-intake cam phase controller 230 for eliminating variation in the intake air amount between the cylinders.

Referring to FIG. 41, the control system 1 further includes an auxiliary exhaust cam phase controller 280. The auxiliary exhaust cam phase controller 280 calculates a control input DUTY_mse to the variable auxiliary exhaust cam phase mechanism 120 in catalyst warmup control, described hereinafter, and is comprised of a target auxiliary exhaust cam phase controller 281, and a fourth SPAS controller 282.

The target auxiliary exhaust cam phase controller 281 calculates a target auxiliary exhaust cam phase θmse_cmd based on the engine speed NE and a target engine speed NE_cmd. More specifically, the target auxiliary exhaust cam phase θmse_cmd is calculated with a control algorithm expressed by equations (54) to (56) in FIG. 42. In the equation (54) in FIG. 42, the symbol θmse_ast represents a catalyst warmup value, as described hereinafter, to which the target auxiliary exhaust cam phase is set by table lookup, and the symbol dθmse represents a correction amount calculated with a response-specifying control algorithm (sliding mode control algorithm or back-stepping control algorithm) expressed by equations (55) and (56) in FIG. 42. In the equation (55), the symbols Kastr and Kasta represent feedback gains, and the symbol σvast represents a switching function defined by the equation (56). Further, in the equation (56), the symbol Sast represents a switching function-setting parameter set to a value within a range of −1<Sast<0, and the symbol NE_cmd represents the target engine speed set to a predetermined fixed value (e.g. 1800 rpm).

The fourth SPAS controller 282 calculates a control input DUTY_(—0) mse to the variable auxiliary exhaust cam phase mechanism 120 such that the auxiliary exhaust cam phase θmse converges to the target auxiliary exhaust cam phase θmse_cmd calculated as above. To be specific, the control input DUTY_(—0) mse is calculated with the same algorithm as the control algorithm of the second SPAS controller 225 described above, and hence description thereof is omitted.

As described above, the auxiliary exhaust cam phase controller 280 calculates the target auxiliary exhaust cam phase θmse_cmd based on the engine speed NE and the target engine speed NE_cmd, and determines a control input DUTY_(—0) mse to the variable auxiliary exhaust cam phase mechanism 120 such that the auxiliary exhaust cam phase θmse converges to the target auxiliary exhaust cam phase θmse_cmd. This makes it possible to accurately control the engine speed NE to the target engine speed NE_cmd.

Hereinafter, an engine control process carried out by the ECU 2 will be described with reference to FIG. 43. This figure shows a flowchart of a main routine for carrying out the engine control process. In this program, first, in a step 1 (shown as S1 in abbreviated form in FIG. 43; the following steps are also shown in abbreviated form), a fuel control process is carried out. This process is performed to calculate the demanded drive torque TRQ_eng, the main fuel injection ratio Rt_Pre, the cylinder intake air amount Gcyl, the target intake air amount Gcyl_cmd, and fuel injection amounts TOUT_main and Tout_sub, depending on operating conditions of the engine 3. Details of the process will be described hereinafter.

Then, in a step 2, a boost pressure control process is carried out. This process is for calculating a control input Dut_wg to the wastegate valve 10 d depending on the operating conditions of the engine 3, and details thereof will be described hereinafter.

Next, in a step 3, an intake valve control process is carried out. This process is for calculating the aforementioned control inputs DUTY_ml, DUTY_msi, and DUTY_ssi#2 to DUTY_ssi#4 depending on the operating conditions of the engine 3, and details thereof will be described hereinafter.

Next, in a step 4, an exhaust valve control process is carried out. This process is for calculating the aforementioned control inputs DUTY_mse, DUTY_mse, and DUTY_sse#2 to DUTY_sse#4, depending on the operating conditions of the engine 3, and details thereof will be described hereinafter.

Next, in a step 5, a throttle valve control process is carried out. This process is for calculating the aforementioned control input DUTY_th depending on the operating conditions of the engine 3, and details thereof will be described hereinafter.

Then, in a step 6, an ignition timing control process is carried out, followed by terminating the present program. Although detailed description of the ignition timing control process is omitted, this process is for calculating ignition timing θig, in which a mixture is ignited by the spark plug 5, depending on the operating conditions of the engine 3. More specifically, the ignition timing θig is set to a value advanced with respect to a value θigidle (see FIG. 66) for normal idling, during the starting control of the engine 3 (engine starting control), and then it is set to a value retarded with respect to the value θ igidle during execution of catalyst warmup control after the start of the engine 3, i.e. retard control of the ignition timing is carried out. Further, during normal operation of the engine 3, the ignition timing θig is set depending on the operating conditions of the engine 3.

Next, the fuel control process executed in the step 1 will be described with reference to FIG. 44. As shown in FIG. 44, in the present program, first, it is determined in a step 10 whether or not an intake/exhaust valve failure flag F_VLVNG or a throttle valve failure flag F_THNG is equal to 1. The intake/exhaust valve failure flag F_VLVNG is set to 1 when the variable intake valve actuation assembly 40 or the variable exhaust valve actuation assembly 90 is faulty, whereas when both of the units 40 and 90 are normal, it is set to 0. Further, the throttle valve failure flag F_THNG is set to 1 when the throttle valve mechanism 16 is faulty, whereas when the throttle valve mechanism 16 is normal, it is set to 0.

If the answer to the question of the step 10 is negative (NO), i.e. if the variable intake valve actuation assembly 40, the variable exhaust valve actuation assembly 90, and the throttle valve mechanism 16 are all normal, the program proceeds to a step 11, wherein the demanded drive torque TRQ_eng is calculated according to the engine speed NE and the accelerator pedal opening AP by searching a map shown in FIG. 45.

The predetermined values AP1 to AP3 of the accelerator pedal opening AP in FIG. 45 are set such that they have a relationship of AP1>AP2>AP3, and the predetermined value AP1 is set to the maximum value of the accelerator pedal opening AP, i.e. the maximum stepped-on amount of the accelerator pedal. As shown in FIG. 45, in the map, the demanded drive torque TRQ_eng is set to a larger value within a range of NE≦NER2 (predetermined value), as the engine speed NE is higher and as the accelerator pedal opening AP is larger. This is because the demanded engine torque is larger as the load on the engine 3 is larger. It should be noted that when AP=AP1 holds, the demanded drive torque TRQ_eng is set to the maximum value within a range of NER1 (predetermined value)<NE≦NER2. Further, within a range of NER2<NE, the demanded drive torque TRQ_eng is set to a larger value, as the accelerator pedal opening AP is larger, and set to a smaller value as the engine speed NE is higher. This is due to the output characteristic of the engine torque with respect to the engine speed NE.

In a step 12 following the step 11, it is determined whether or not the demanded drive torque TRQ_eng calculated in the step 11 is smaller than a predetermined stratified combustion operation threshold value TRQ_disc. It should be noted that the term “stratified combustion operation” is intended to mean operation in which fuel injection into each cylinder from the main fuel injection valve 4 is performed during the compression stroke of the piston to thereby cause stratified combustion of the mixture.

If the answer to the question of the step 12 is affirmative (YES), i.e. if the stratified combustion operation should be effected, the program proceeds to a step 13, wherein a target air-fuel ratio KCMD_disc for the stratified combustion operation is calculated by searching a table, not shown, according to the demanded drive torque TRQ_eng. In this table, the target air-fuel ratio KCMD_disc for the stratified combustion operation is set to a value within a predetermined very lean region (e.g. A/F=30 to 40).

Then, the program proceeds to a step 14, wherein the target air-fuel ratio KCMD is set to the target air-fuel ratio KCMD_disc for the stratified combustion operation. After that, the program proceeds to a step 15, wherein the main fuel injection ratio Rt_Pre is set to a predetermined maximum value Rtmax (100%). This causes fuel injection from the auxiliary fuel injection valve 15 to be stopped, as described hereinafter. Then, the program proceeds to a step 16, wherein the cylinder intake air amount Gcyl and the target intake air amount Gcyl_cmd are calculated.

The cylinder intake air amount Gcyl and the target intake air amount Gcyl_cmd are calculated specifically by a program shown in FIG. 46. That is, first, in a step 30 in FIG. 46, the cylinder intake air amount Gcyl is calculated by the above-mentioned equation (1).

Then, in a step 31, a basic value Gcyl_cmd_base of the target intake air amount is calculated according to the engine speed NE and the demanded drive torque TRQ_eng, by searching a map shown in FIG. 47. It should be noted that predetermined values TRQ_eng 1 to TRQ_eng 3 of the demanded drive torque in this map are set such that they have a relationship of TRQ_eng 1>TRQ_eng 2>TRQ_eng 3. As shown in FIG. 47, the basic value Gcyl_cmd_base of the target intake air amount is set to a larger value, as the engine speed NE is higher, or the demanded drive torque TRQ_eng is larger. This is because as the load on the engine 3 is larger, a larger output of the engine is demanded, which demands a larger intake air amount.

Then, in a step 32, an air-fuel ratio correction coefficient Kgcyl_af is calculated according to the target air-fuel ratio KCMD, by searching a table shown in FIG. 48. In this table, the air-fuel ratio correction coefficient Kgcyl_af is set to a smaller value, as the target air-fuel ratio KCMD is a richer value. This is because the required intake air amount becomes smaller as the air-fuel ratio of the mixture is controlled to be richer. It should be noted that a value KCMDST in FIG. 48 corresponds to a stoichiometric air-fuel ratio.

Next, the program proceeds to a step 33, wherein the product (Kgcyl_af·Gcyl_cmd_base) of the basic value of the target intake air amount and the air-fuel ratio correction coefficient is set to the target intake air amount Gcyl_cmd, followed by terminating the present program.

Referring again to FIG. 44, after execution of the step 16 as described above, the program proceeds to a step 17, wherein a fuel injection control process is carried out. This process is for calculating control inputs to the main and auxiliary fuel injection valves 4 and 15, in the following manner:

First, the main fuel injection amount TOUT_main, which is the fuel injection amount of the main fuel injection valve 4 and the auxiliary fuel injection amount Tout_sub, which is the fuel injection amount of the auxiliary fuel injection valve 15, are calculated. More specifically, a final cylinder-by-cylinder total fuel injection amount TOUT is calculated for each cylinder based on the operating conditions of the engine 3 and the target air-fuel ratio KCMD described above, and then the main and auxiliary fuel injection amounts TOUT_main and Tout_sub are calculated, respectively, by the following equations (57) and (58):

TOUT_main=[TOUT·Rt _(—) Pre]/100  (57)

TOUT_sub=[TOUT·(100−Rt _(—) Pre)]/100  (58)

Referring to the equation (58), when Rt_Pre=Rtmax (100 (%)) holds, TOUT_sub=0 holds, from which it is understood that the fuel injection from the auxiliary fuel injection valve 15 is stopped.

Then, the control inputs to the main and auxiliary fuel injection valves 4 and 15 are calculated according to the main and auxiliary fuel injection amounts TOUT_main and Tout_sub, by searching respective tables, not shown. After execution of the step 17 as described above, the present program is terminated.

On the other hand, if the answer to the question of the step 12 is negative (NO), it is judged that the engine 3 should be operated not in a stratified combustion operation mode but in a premixture lean operation mode as one of homogeneous combustion operation modes, and the program proceeds to a step 18, wherein a target air-fuel ratio KCMD_lean for the premixture lean operation is calculated according to the demanded drive torque TRQ_eng by searching a table, not shown. It should be noted that in this table, the target air-fuel ratio KCMD_lean for the premixture lean operation is set to a value within a predetermined lean region (e.g. A/F=18 to 21).

Next, the program proceeds to a step 19, wherein the target air-fuel ratio KCMD is set to the target air-fuel ratio KCMD_lean for the premixture lean operation. Then, in a step 20, the main fuel injection ratio Rt_Pre is calculated according to the demanded drive torque TRQ_eng by searching a table shown in FIG. 49. In the following tables and maps including the map in FIG. 49, predetermined values TRQ_idle, TRQ_disc, TRQott, and TRQ1 to TRQ4, of the demanded drive torque TRQ_eng are set such that they have a relationship of TRQ_idle<TRQ_disc<TRQ1<TRQott<TRQ2<TRQ3<TRQ4. Further, TRQ_idle represents a predetermined value for idling operation of the engine 3.

As shown in FIG. 49, in the table, within a range of TRQ1<TRQ_eng<TRQ4, the main fuel injection ratio Rt_Pre is set to a smaller value as the demanded drive torque TRQ_eng is larger. This is for the following reason: As the demanded drive torque TRQ_eng is larger, the boost pressure Pc is controlled to be higher, which causes a rise in the temperature of the intake air, so that knocking in the engine 3 becomes liable to occur. Therefore, to prevent occurrence of such knocking, it is necessary to increase the effect of cooling the intake air by the fuel evaporation cooling device 12 by increasing the fuel injection amount Tout_sub of the auxiliary fuel injection valve 15. Hence, the main fuel injection ratio Rt_Pre is set as above.

Further, in the table, the main fuel injection ratio Rt_Pre is set to a predetermined minimum value Rtmin (10(%)), in a range where the demanded drive torque TRQ_eng is not smaller than the predetermined value TRQ4, and set to the predetermined maximum value Rtmax in a range where the demanded drive torque TRQ_eng is not larger than the predetermined value TRQ1.

After execution of the step 20, the steps 16 and 17 are carried out, followed by terminating the present program.

On the other hand, if the answer to the question of the step 10 is affirmative (YES), i.e. if any of the variable intake valve actuation assembly 40, the variable exhaust valve actuation assembly 90, and the throttle valve mechanism 16 is faulty, the program proceeds to a step 21, wherein the demanded drive torque TRQ_eng is set to a predetermined value TRQ_fs for a failure time. After that, the program proceeds to a step 22, wherein the main fuel injection ratio Rt_Pre is set to the aforementioned maximum value Rtmax. Then, the steps 16 and 17 are carried out as described hereinabove, followed by terminating the present program.

Next, the boost pressure control process will be described with reference to FIG. 50. As shown in FIG. 50, in the program for this process, first, it is determined in a step 40 whether or not the intake/exhaust valve failure flag F_VLVNG or the throttle valve failure flag F_THNG is equal to 1.

If the answer to the above question is negative (NO), i.e. if the variable intake valve actuation assembly 40, the variable exhaust valve actuation assembly 90, and the throttle valve mechanism 16 are all normal, the program proceeds to a step 41, wherein it is determined whether or not an engine start flag F_ENGSTART is equal to 1. The engine start flag F_ENGSTART is set by determining in a determination process, not shown, from the engine speed NE and the output of the IG·SW 36 whether or not the engine starting control, i.e. cranking of the engine 3 is being executed. More specifically, when the engine starting control is being carried out, the engine start flag F_ENGSTART is set to 1, and otherwise set to 0.

If the answer to the question of the step 41 is affirmative (YES), i.e. if the engine starting control is being executed, the program proceeds to a step 43, wherein the control input Dut_wg to the wastegate valve 10 d is set to a predetermined fully-opening value Dut_wgmax, followed by terminating the present program. As a result, the wastegate valve 10 d is controlled to a fully-open state, whereby the supercharging operation by the turbocharger device 10 is substantially stopped.

On the other hand, if the answer to the question of the step 41 is negative (NO), i.e. if the engine starting control is not being executed, the program proceeds to a step 42, wherein it is determined whether or not an execution time period Tcat for measuring a time period over which the catalyst warmup control has been executed and which is represented by a time period elapsed immediately after termination of the start of the engine 3, is shorter than a predetermined time period Tcatlmt (e.g. 30 sec). The catalyst warmup control is executed for rapidly activating catalyst in the catalytic converters 19 a and 19 b after the start of the engine 3.

If the answer to the question of the step 42 is affirmative (YES), i.e. if Tcat<Tcatlmt holds, the program proceeds to a step 44, wherein it is determined whether or not the accelerator pedal opening AP is smaller than a predetermined value APREF. This predetermined value APREF is used for determining that the accelerator pedal is not stepped on, and set to a value (e.g. one degree) from which it can be determined that the accelerator pedal is not stepped on.

If the answer to the question of the step 44 is affirmative (YES), i.e. if the accelerator pedal is not stepped on, it is judged that the catalyst warmup control should be executed, so that the program proceeds to a step 45, wherein similarly to the step 43, the control input Dut_wg to the wastegate valve 10 d is set to the above fully-opening value Dut_wgmax, followed by terminating the present program.

On the other hand, if the answer to the question of the step 42 or the step 44 is negative (NO), i.e. if the engine starting control is not being executed, and at the same time if Tcat≧Tcatlmt holds or if the accelerator pedal is stepped on, the program proceeds to a step 46, wherein a basic value DUT_wg_bs of the control input Dut_wg is calculated according to the demanded drive torque TRQ_eng by searching a table shown in FIG. 51.

As shown in FIG. 51, in this table, within a range of TRQ1<TRQ_eng<TRQ2, the basic value Dut_wg_bs is set to a smaller value, as the demanded drive torque TRQ_eng is larger. This is because to increase the charging efficiency by the supercharging operation, it is required to make the boost pressure Pc higher as the demanded drive torque TRQ_eng is larger. Further, within a range of TRQ2≦TRQ_eng≦TRQ3, the basic value DUT_wg_bs is set to a predetermined fully-closing value Dut_wgmin. This is to attain a maximum supercharging effect in response to engine load in a high-load region. Further, within a range of TRQ3<TRQ_eng, the basic value DUT_wg_bs is set to a smaller value as the demanded drive torque TRQ_eng is larger. This is to prevent occurrence of knocking in the engine 3.

Next, in a step 47, a target boost pressure Pc_cmd is calculated according to the demanded drive torque TRQ_eng, by searching a table shown in FIG. 52. As shown in FIG. 52, in this table, within a range of TRQ_idle<TRQ_eng<TRQ2, the target boost pressure Pc_cmd is set to a larger value as the demanded drive torque TRQ_eng is larger. This is to increase the charging efficiency by the supercharging operation, as described above. Further, within a range of TRQ2<TRQ_eng≦TRQ3, the target boost pressure Pc_cmd is set to a predetermined value. This is to attain the maximum supercharging effect, as described hereinabove. Furthermore, within a range of TRQ3<TRQ_eng<TRQ4, the target boost pressure Pc_cmd is set to a smaller value as the demanded drive torque TRQ_eng is larger. This is to prevent occurrence of knocking in the engine 3. The symbol Patm in FIG. 52 represents atmospheric pressure. The same applies to FIG. 53 et. seq., referred to hereinafter.

Next, the program proceeds to a step 48, wherein the control input Dut_wg is calculated with an I-P control algorithm expressed by the following equation (59), followed by terminating the present program. Thus, the boost pressure Pc is feedback controlled such that it converges to the target boost pressure Pc_cmd.

Dut _(—) wg=Dut _(—) wg _(—) bs+Kpwg·Pc+Kiwg·Σ(Pc−Pc _(—) cmd)  (59)

wherein, Kpwg represents a P term gain, and Kiwg an I term gain.

On the other hand, if the answer to the question of the step 40 is affirmative (YES), i.e. if any of the variable intake valve actuation assembly 40, the variable exhaust valve actuation assembly 90, and the throttle valve mechanism 16 is faulty, the program proceeds to a step 49, wherein similarly to the steps 43 and 45 described above, the control input Dut_wg to the wastegate valve 10 d is set to the fully-opening value Dut_wgmax, followed by terminating the present program.

Next, the aforementioned intake valve control process in the step 3 will be described with reference to FIGS. 53 and 54. As shown in FIG. 53, in the program for this process, first, it is determined in a step 60 whether or not the intake/exhaust valve failure flag F_VLVNG is equal to 1. If the answer to this question is negative (NO), i.e. if the variable intake valve actuation assembly 40 and the variable exhaust valve actuation assembly 90 are both normal, the program proceeds to a step 61, wherein it is determined whether or not the engine start flag F_ENGSTART is equal to 1.

If the answer to this question is affirmative (YES), i.e. if the engine starting control is being executed, the program proceeds to a step 62, wherein a target main intake cam phase θmi_cmd, which is a target value of the main intake cam phase θmi, is set to a predetermined idling value θmi_idle for idling of the engine 3.

Then, the program proceeds to a step 63, wherein the target auxiliary intake cam phase θmsi_cmd is set to a predetermined start value θmsi_st for starting of the engine 3. The predetermined start value θmsi_st is set as a predetermined value for the retarded closing of the intake valve 6. After that, the program proceeds to a step 64, wherein the target inter-intake cam phases θssi#i_cmd (#i=#2 to #4) are all set to 0.

Next, the program proceeds to a step 65 in FIG. 54, wherein the control input DUTY_ml to the variable main intake cam phase mechanism 60 is calculated according to the target main intake cam phase θmi_cmd by searching a table, not shown. Thereafter, in the following step 66, the control input DUTY_msi to the variable auxiliary intake cam phase mechanism 70 is calculated according to the target auxiliary intake cam phase θmsi_cmd by searching a table, not shown. It should be noted that in the step 66, the control input DUTY_msi may be calculated by the same method as employed in a step 75 referred to hereinafter.

Then, in a step 67, the control inputs DUTY_ssi#i to the variable inter-intake cam phase mechanisms 80 are calculated according to the target inter-intake cam phases θssi#i_cmd by searching a table, not shown, followed by terminating the present program.

Referring again to FIG. 53, if the answer to the question of the step 61 is negative (NO), i.e. if the engine starting control is not being executed, the program proceeds to a step 68, wherein it is determined whether or not the above-mentioned execution time period Tcat for the catalyst warmup control is shorter than the predetermined value Tcatlmt. If the answer to this question is affirmative (YES), the program proceeds to a step 69, wherein it is determined whether or not the accelerator pedal opening AP is smaller than the predetermined value APREF.

If the answer to the question of the step 69 is affirmative (YES), i.e. if the accelerator pedal is not stepped on, it is judged that the catalyst warmup control should be performed, so that the program proceeds to a step 70, wherein the target main intake cam phase θmi_cmd is set to the predetermined idling value θmi_idle mentioned above.

Then, the program proceeds to a step 71, wherein a catalyst warmup value θmsi_cw of the target auxiliary intake cam phase is calculated according to the execution time period Tcat for the catalyst warmup control by searching a table shown in FIG. 55. In this figure, the symbol θmsiott represents an Otto phase value (=a cam angle of 90 degrees) of the auxiliary intake cam phase θmsi, which causes the valve timing of the intake valve 6 to coincide with that of the intake valve driven by the Otto intake cam. The same applies to the following description.

Then, in a step 72, the target auxiliary intake cam phase θmsi_cmd is set to the catalyst warmup value θmsi_cw, whereafter in a step 73, the target inter-intake cam phases θssi#i_cmd (#i=#2 to #4) are all set to 0, similarly to the step 64 described above.

Next, the program proceeds to a step 74 in FIG. 54, wherein the control input DUTY_ml to the variable main intake cam phase mechanism 60 is calculated-according to the target main intake cam phase θmi_cmd and the main intake cam phase θmi. This control input DUTY_ml is calculated with the same algorithm as the aforementioned control algorithm of the second SPAS controller 225.

Then, in a step 75, with the control algorithm of the second SPAS controller 225, the control input DUTY_msi to the variable auxiliary intake cam phase mechanism 70 is calculated. More specifically, the control input DUTY_msi is calculated with the prediction algorithm expressed by the equation (29), the identification algorithm expressed by the equations (30) to (35), and the sliding mode control algorithm expressed by the equations (36) to (41).

Next, in a step 76, the control inputs DUTY_ssi#i (#i=#2 to #4) to the variable inter-intake cam phase mechanisms 80 are calculated according to the target inter-intake cam phases θssi#i_cmd calculated in the step 73 and the inter-intake cam phase θssi#i with the control algorithm of the third SPAS controller 262, followed by terminating the present program. The control inputs DUTY_ssi#i are calculated with the same algorithm as the control algorithm of the second SPAS controller 225, as described above, i.e. the control algorithm used for calculation of the control input DUTY_msi.

Referring again to FIG. 53, if the answer to the question of the step 68 or the step 69 is negative (NO), i.e. if the engine starting control is not being executed, and at the same time if Tcat≧Tcatlmt holds, or if the accelerator pedal is stepped on, the program proceeds to a step 77, wherein a normal operation value θmi_drv of the target intake cam phase is calculated according to the demanded drive torque TRQ_eng and the engine speed NE by searching a map shown in FIG. 56.

In FIG. 56, predetermined values NE1 to NE3 of the engine speed NE are set such that they have a relationship of NE1>NE2>NE3. The same applies to the following description. In this map, the normal operation value θmi_drv is set to a more advanced value as the demanded drive torque TRQ_eng is larger or the engine speed NE is higher. This is to properly secure the output of the engine 3, by advancing the main intake cam phase θmi and thereby advancing the opening/closing timing of the intake valve 6 as the load on the engine is higher.

Then, in a step 78, the target main intake cam phase θmi_cmd is set to the normal operation value θmi_drv. After that, the program proceeds to a step 79, wherein the above-described basic value θmsi_base of the auxiliary intake cam phase θmsi is calculated according to the demanded drive torque TRQ_eng by searching a table shown in FIG. 57.

As shown in FIG. 57, in this table, the basic value θmsi_base is set to a fixed value on the retarded-closing side, within a range of TRQ_eng<TRQ_disc, i.e. in a stratified combustion operating region of the engine 3. This is to stabilize the combustion state in such a low-load region where the stratified combustion operation is carried out. Further, the basic value θmsi_base is set such that within a range of TRQ_disc≦TRQ_eng≦TRQott, the degree of the retarded closing of the intake valve 6 becomes smaller as the demanded drive torque TRQ_eng is larger. This is to avoid an increase in the amount of blowback of fuel into the intake manifold, which is caused according to the degree of retarded closing of the intake valve 6, as the demanded drive torque TRQ_eng is larger. Further, when TRQ_eng=TRQott holds, the basic value θmsi_base is set to the Otto phase value θmsiott.

Further, the basic value θmsi_base is set such that within a range of TRQott<TRQ_eng<TRQ2, the degree of advanced closing of the intake valve 6 becomes larger as the demanded drive torque TRQ_eng is larger. This is to increase combustion efficiency by high expansion-ratio cycle operation.

Further, the basic value θmsi_base is set such that within a range of TRQ2≦TRQ_eng<TRQ4, the degree of advanced closing of the intake valve 6 becomes smaller as the demanded drive torque TRQ_eng is larger. This is for the following reason: In such a high-load region as in the range of TRQ2≦TRQ_eng<TRQ4, the supercharging operation is limited so as to prevent occurrence of knocking in the engine 3, as described hereinafter, so that if the degree of advanced closing of the intake valve 6 is controlled to be large in a state of the charging efficiency being reduced by the limitation of the supercharging operation, torque generated by the engine 3 is decreased. Therefore, to compensate for the decrease in the torque generated by the engine 3, the basic value θmsi_base is set such that the degree of advanced closing of the intake valve 6 becomes smaller, as the demanded drive torque TRQ_eng is larger.

In a step 80 following the step 79, the target auxiliary intake cam phase θmsi_cmd is calculated with the aforementioned control algorithm of the first SPAS controller 221. More specifically, the target auxiliary intake cam phase θmsi_cmd is calculated with the prediction algorithm expressed by the equation (7), the identification algorithm expressed by the equations (8) to (13), and the sliding mode control algorithm expressed by the equations (15) to (21).

Then, in a step 81, the target inter-intake cam phases θssi#i_cmd (#i=#2 to #4) are calculated with the control algorithm of the inter-intake cam phase controller 230 described above. More specifically, the intake air amount variation coefficients Φ#1 to Φ#4 are identified with the identification algorithm expressed by the equations (44) to (50); the differences EΦ#2 to EΦ#4 of the intake air amount variation coefficients Φ#2 to Φ#4 with respect to the intake air amount variation coefficient Φ#1 are calculated by the equation (51); and the target inter-intake cam phases θssi#i_cmd are calculated with the response-specifying control algorithm expressed by the equations (52) and (53) such that the differences EΦ#2 to EΦ#4 converge to a value of 0. Then, the steps 74 to 76 in FIG. 54 are carried out, as described hereinbefore, followed by terminating the present program.

Referring again to FIG. 53, if the answer to the question of the step 60 is affirmative (YES), i.e. if the variable intake valve actuation assembly 40 or the variable exhaust valve actuation assembly 90 is faulty, the program proceeds to a step 82, wherein the target main intake cam phase θmi_cmd is set to the predetermined idling value θmi_idle. Then, the program proceeds to a step 83, wherein the target auxiliary intake cam phase θmsi_cmd is set to a predetermined failsafe value θmsi_fs.

Then, the program proceeds to a step 84, wherein similarly to the steps 64 and 73, the target inter-intake cam phases θssi#i_cmd (#i=#2 to #4) are all set to 0. After that, as described above, the steps 65 to 67 in FIG. 54 are carried out, followed by terminating the present program.

Next, the aforementioned exhaust valve control process in the step 4 will be described with reference to FIGS. 58 and 59. As shown in FIG. 58, in this program, first, it is determined in a step 90 whether or not the intake/exhaust valve failure flag F_VLVNG is equal to 1. If the answer to this question is negative (NO), i.e. if the variable intake valve actuation assembly 40 and the variable exhaust valve actuation assembly 90 are both normal, the program proceeds to a step 91, wherein it is determined whether or not the engine start flag F_ENGSTART is equal to 1.

If the answer to this question is affirmative (YES), i.e. if the engine starting control is being executed, the program proceeds to a step 92, wherein a target main exhaust cam phase θme_cmd, which is a target value of the main exhaust cam phase θme, is set to a predetermined idling value θme_idle for idling of the engine 3.

Then, the program proceeds to a step 93, wherein the target auxiliary exhaust cam phase θmse_cmd is set to a predetermined start value θmse_st for starting of the engine 3. The predetermined start value θmse_st is set as a predetermined value for the retarded closing of the exhaust valve 7. After that, the program proceeds to a step 94, wherein the target inter-exhaust cam phases θsse#i_cmd (#i=#2 to #4) are all set to 0.

Next, the program proceeds to a step 95 in FIG. 59, wherein the control input DUTY_me to the variable main exhaust cam phase mechanism 110 is calculated according to the target main exhaust cam phase θme_cmd by searching a table, not shown. Then, in a step 96, the control input DUTY_mse to the variable auxiliary exhaust cam phase mechanism 120 is calculated according to the target auxiliary exhaust cam phase θmse_cmd by searching a table, not shown. It should be noted that in the step 96, the control input DUTY_mse may be calculated by the same method as employed in a step 106 referred to hereinafter.

Next, in a step 97, control inputs DUTY_sse#i to the variable inter-exhaust cam phase mechanisms 130 are calculated according to the target inter-intake cam phases θsse#i_cmd by searching a table, not shown, followed by terminating the present program.

Referring again to FIG. 58, if the answer to the question of the step 91 is negative (NO), i.e. if the engine starting control is not being executed, the program proceeds to a step 98, wherein it is determined whether or not the above-mentioned execution time period Tcat for the catalyst warmup control is shorter than the predetermined value Tcatlmt. If the answer to this question is affirmative (YES), the program proceeds to a step 99, wherein it is determined whether or not the accelerator pedal opening AP is smaller than the predetermined value APREF.

If the answer to this question is affirmative (YES), i.e. if the accelerator pedal is not stepped on, it is judged that the catalyst warmup control should be performed, and the program proceeds to a step 100, wherein the target main exhaust cam phase θme_cmd is set to the predetermined idling value θme_idle mentioned above.

Then, the program proceeds to a step 101, wherein the catalyst warmup value θmse_ast of the target auxiliary exhaust cam phase is calculated according to the above-mentioned execution time period Tcat for the catalyst warmup control, by searching a table shown in FIG. 60. In this figure, the symbol θmseott represents an Otto phase value (=90 degrees) of the auxiliary exhaust cam phase θmse, which causes the valve timing of the exhaust valve 7 to coincide with that of an exhaust valve actuated by the Otto exhaust cam. As shown in FIG. 60, the catalyst warmup value θmse_ast of the target auxiliary exhaust cam phase is set to values on the retarded-opening side until the execution time period Tcat reaches a predetermined value Tcatref, and thereafter to valves on the advanced-opening side. The reason for thus setting the catalyst warmup value to values on the advanced-opening side is to open the exhaust valve 7 during the expansion stroke of the associated piston, whereby high-temperature exhaust gases are supplied to the catalytic converters 19 a and 19 b to thereby rapidly activate the catalyst in the catalytic converters 19 a and 19 b.

In a step 102 following the step 101, the correction amount dθmse of the target auxiliary exhaust cam phase is calculated with the response-specifying control algorithm expressed by the equations (55) and (56).

Then, the program proceeds to a step 103, wherein the target auxiliary exhaust cam phase θmse_cmd is calculated by the equation (54) described hereinbefore, using the values θmse_ast and dθmse calculated in the step 101 and 102.

Then, in a step 104, similarly to the step 94, the target inter-exhaust cam phases θsse#i_cmd (#i=#2 to #4) are all set to 0. After that, the program proceeds to a step 105 in FIG. 59, wherein the control input DUTY_me to the variable main exhaust cam phase mechanism 110 is calculated according to the target main exhaust cam phase θme_cmd and the main exhaust cam phase θme. The control input DUTY_me is calculated with the same algorithm as the above-described control algorithm of the second SPAS controller 225.

Then, in a step 106, the control input DUTY_mse to the variable auxiliary exhaust cam phase mechanism 120 is calculated with a control algorithm of the fourth SPAS controller 282. More specifically, as described hereinabove, the control input DUTY_mse is calculated with the same algorithm as the control algorithm of the second SPAS controller 225.

Next, the program proceeds to a step 107, wherein the control inputs DUTY_sse#i (#i=#2 to #4) to the variable inter-exhaust cam phase mechanisms 130 are calculated according to the target inter-intake cam phases θsse#i_cmd and inter-intake cam phases θsse#I, followed by terminating the present program. It should be noted that the control inputs DUTY_sse#1 are calculated with the same algorithm as the control algorithm used for calculation of the above control input DUTY_mse.

Referring again to FIG. 58, if the answer to the question of the step 98 or the step 99 is negative (NO), i.e. if the engine starting control is not being executed, and at the same time if Tcat≧Tcatlmt holds or if the accelerator pedal is stepped on, the program proceeds to a step 108, wherein a normal operation value θme_drv of the target main exhaust cam phase is calculated according to the demanded drive torque TRQ_eng and the engine speed NE by searching a map shown in FIG. 61.

As shown in FIG. 61, in this map, the normal operation value θme_drv is set to a more advanced value as the demanded drive torque TRQ_eng is larger or the engine speed NE is higher. This is to enhance exhaust gas-scavenging efficiency to properly secure the output of the engine 3 by advancing the main exhaust cam phase θme and thereby advancing the opening/closing timing of the exhaust valve 7 as the load on the engine is higher.

Then, in a step 109, the target main exhaust cam phase θme_cmd is set to the normal operation value θme_drv. After that, the program proceeds to a step 110, wherein the target auxiliary exhaust cam phase θmse_cmd is set to a predetermined value θmse_base. This predetermined value θmse_base is set to such a value (90 degrees) as will cause the valve timing of the exhaust valve 7 to coincide with that of an exhaust valve actuated by the Otto exhaust cam.

In a step 111 following the step 110, the target inter-exhaust cam phases θsse#i_cmd (#i=#2 to #4) are calculated according to the demanded drive torque TRQ_eng and the engine speed NE by searching a map, not shown. In this map, each target inter-exhaust cam phase θsse#i_cmd is set to a value capable of compensating for variation in the scavenging efficiency between the cylinders caused by pulsation effects of the exhaust system. Then, the steps 105 to 107 in FIG. 59 are carried out, as described above, followed by terminating the present program.

Referring again to FIG. 58, if the answer to the question of the step 90 is affirmative (YES), i.e. if the variable intake valve actuation assembly 40 or the variable exhaust valve actuation assembly 90 is faulty, the program proceeds to a step 112, wherein the target main exhaust cam phase θme_cmd is set to the predetermined idling value θme_idle mentioned above. Then, the program proceeds to a step 113, wherein the target auxiliary exhaust cam phase θmse_cmd is set to a predetermined failsafe value θmse_fs. This predetermined failsafe value θmse_fs is set to such a value (90 degrees) as will cause the valve timing of the exhaust valve 7 to coincide with that of an exhaust valve actuated by the Otto exhaust cam.

Then, the program proceeds to a step 114, wherein similarly to the steps 94 and 104, the target inter-exhaust cam phases θsse#i_cmd (#i=#2 to #4) are all set to 0. After that, as described above, the steps 95 to 97 in FIG. 59 are carried out, followed by terminating the present program.

Next, the above-mentioned throttle valve control process in the step 5 will be described with reference to FIG. 62. As shown in FIG. 62, in the program of this process, first, it is determined in a step 120 whether or not the intake/exhaust valve failure flag F_VLVNG is equal to 1. If the answer to this question is negative (NO), i.e. if the variable intake valve actuation assembly 40 and the variable exhaust valve actuation assembly 90 are both normal, the program proceeds to a step 121, wherein it is determined whether or not the engine start flag F_ENGSTART is equal to 1.

If the answer to this question is affirmative (YES), i.e. if the engine starting control is being executed, the program proceeds to a step 122, wherein the target opening degree TH_cmd is set to a predetermined start value THcmd_st. This predetermined start value THcmd_st is set to a value slightly larger than an idling value THcmd_idle, referred to hereinafter. Then, the program proceeds to a step 123, wherein the control input DUTY_th to the throttle valve mechanism 16 is calculated, followed by terminating the present program. The control input DUTY_th is specifically calculated according to the target opening degree TH_cmd by searching a table, not shown.

On the other hand, if the answer to the question of the step 121 is negative (NO), i.e. if the engine starting control is not being executed, the program proceeds to a step 124, wherein it is determined whether or not the above-mentioned execution time period Tcat for the catalyst warmup control is shorter than the predetermined value Tcatlmt. If the answer to this question is affirmative (YES), the program proceeds to a step 125, wherein it is determined whether or not the accelerator pedal opening AP is smaller than the predetermined value APREF.

If the answer to the question of the step 125 is affirmative (YES), i.e. if the accelerator pedal is not stepped on, it is judged that the catalyst warmup control should be performed, so that the program proceeds to a step 126, wherein a catalyst warmup value THcmd_ast of the target opening degree is calculated according to the above-mentioned execution time period Tcat for the catalyst warmup control, by searching a table shown in FIG. 63.

In FIG. 63, the symbol THcmd_idle represents an idling value used for idling of the engine 3. As shown in FIG. 63, in this table, the catalyst warmup value THcmd_ast is set to a larger value as the execution time period Tcat is shorter, before the execution time period Tcat reaches a predetermined value Tcat1, whereas after the execution time period Tcat has reached the predetermined value Tcat1, the catalyst warmup value THcmd_ast is set to the idling value THcmd_idle.

Then, the program proceeds to a step 127, wherein the target opening degree TH_cmd is set to the catalyst warmup value THcmd_ast. Then, the step 123 is carried out, as described above, followed by terminating the present program.

On the other hand, if the answer to the question of the step 124 or the step 125 is negative (NO), i.e. if the engine starting control is not being executed, and at the same time if Tcat≧Tcatlmt holds or if the accelerator pedal is stepped on, the program proceeds to a step 128, wherein a normal operation value THcmd_drv of the target opening degree is calculated according to the demanded drive torque TRQ_eng and the engine speed NE by searching a map shown in FIG. 64.

As shown in FIG. 64, in this map, the normal operation value THcmd_drv is set to a larger value, as the demanded drive torque TRQ_eng is larger or the engine speed NE is higher. This is because as the load on the engine 3 is higher, a larger amount of intake air is required to secure a larger output of the engine.

Then, in a step 129, the target opening degree TH_cmd is set to the normal operation value THcmd_drv. Thereafter, the step 123 is carried out, as described above, followed by terminating the present program.

On the other hand, if the answer to the question of the step 120 is affirmative (YES), i.e. if the variable intake valve actuation assembly 40 or the variable exhaust valve actuation assembly 90 is faulty, the program proceeds to a step 130, wherein a failsafe value THcmd_fs of the target opening degree is calculated according to the accelerator pedal opening AP and the engine speed NE by searching a map shown in FIG. 65. As shown in FIG. 65, in this map, the failsafe value THcmd_fs is set to a larger value as the accelerator pedal opening AP is larger or as the engine speed NE is higher. This is for the same reason as described above as to the calculation of the normal operation value THcmd_drv.

Next, the program proceeds to a step 131, wherein the target opening degree TH_cmd is set to the failure-time value THcmd_fs. Then, the step 123 is carried out, as described above, followed by terminating the present program.

It should be noted that by the above control processes, each of the control inputs DUTY_ml, DUTY_msi, DUTY_ssi#i, DUTY_me, DUTY_mse, DUTY_sse#i, and DUTY_th is set to one of a pulse signal, a current signal, and a voltage signal, of which the duty ratio is set according to the result of the calculation.

Next, a description will be given of operation of the engine control, described above, by the control system, mainly of operations executed during starting of the engine and the catalyst warmup control, with reference to FIG. 66.

As shown in FIG. 66, during engine starting control (from t0 to t1), the target auxiliary intake cam phase θmsi_cmd is set to the predetermined start value θmsi_st (step 63), whereby the auxiliary intake cam phase θmsi is controlled to a value on the retarded-closing side, and at the same time the target opening degree TH_cmd is set to the predetermined start value THcmd_st (step 122). Thus, the throttle valve opening TH is controlled to a half-open state. As a result, the cylinder intake air amount Gcyl is controlled to a value small but large enough to start the engine 3. Thus, at the start of the engine 3, the cylinder intake air amount Gcyl, which cannot be controlled only by throttling of the throttle valve 17, can be decreased to a value just enough to start the engine 3, so that it is possible to accordingly reduce the fuel injection amount. This makes it possible to reduce the volume of exhaust gases, thereby making it possible to reduce the total amount of unburned components in exhaust gases, emitted during engine starting control.

Further, since the target auxiliary exhaust cam phase θmse_cmd is set to the predetermined start value θmse_st (step 93), the auxiliary exhaust cam phase θmse can be controlled to the retarded-opening side, whereby combustion gases are held within the cylinders for a longer time period, thereby making it possible to reduce unburned HC in exhaust gases. Further, the target air-fuel ratio KCMD is controlled to a slightly richer value than the value KCMDST corresponding to the stoichiometric air-fuel ratio, and at the same time the ignition timing θig is controlled to a value advanced with respect to the value θigidle for normal idling of the engine 3, whereby it is possible to enhance the ignitability of the mixture.

When the engine 3 is completely started (started to perform complete combustion) through the engine starting control (time t1), the catalyst warmup control starts to be carried out. More specifically, the target auxiliary intake cam phase θmsi_cmd is set to the catalyst warmup value θmsi_cw (step 72), whereby the auxiliary intake cam phase θmsi is controlled such that it becomes closer to the Otto phase value θmsiott from the retarded-closing side. This reduces the degree of retarded closing of the intake valve 6 to thereby increase the cylinder intake air amount Gcyl, resulting in the increased volume of exhaust gases. Further, since the target auxiliary exhaust cam phase θmse_cmd is set to the sum of the catalyst warmup value θmse_ast and the correction amount dθmse (step 103), the auxiliary exhaust cam phase θmse is controlled to change from the retarded-opening side to the advanced-opening side, whereby high-temperature exhaust gases are emitted during the compression stroke of the associated piston. In addition, since the ignition timing θig is retarded by a predetermined value dθig, the temperature of exhaust gases is raised. This makes it possible to rapidly activate catalyst in the catalytic converters 19 a and 19 b.

Further, due to control of the target air-fuel ratio KCMD to values on the lean side, it is possible to reduce unburned HC in exhaust gases. Further, the engine speed NE is controlled to be equal to the target engine speed NE_cmd.

Furthermore, after termination of the catalyst warmup control (after t2), normal operation control is carried out based on the program described above, depending on the operating conditions of the engine 3, including the demanded drive torque TRQ_eng.

Next, operation executed by the control system during normal operation control will be described with reference to FIG. 67, for each of the following ranges (L1) to (L6) of the demanded drive torque TRQ_eng.

TRQ_idle≦TRQ_eng<TRQ_disc  (L1)

In this range, according to the setting of the basic value θmsi_base described above, the auxiliary intake cam phase θmsi is controlled to an approximately fixed value on the retarded-closing side. Further, since the amount of intake air is not decreased by the throttle valve 17, the intake pipe absolute pressure PBA is controlled to an approximately fixed value slightly lower then the atmospheric pressure Patm. Furthermore, the cylinder intake air amount Gcyl is controlled to an approximately fixed value. The main fuel injection ratio Rt_Pre is set to the maximum value Rtmax; the target air-fuel ratio KCMD is set to a value within the very lean region mentioned above; and the stratified combustion operation is carried out.

TRQ_disc≦TRQ_eng≦TRQ1  (L2)

In this range, according to the setting of the basic value θmsi_base described above, the auxiliary intake cam phase θmsi is controlled to a value considerably retarded with respect to the value thereof set when the demanded drive torque TRQ_eng is within the above-described range (L1), and at the same time such that the degree of the retarded closing of the intake valve 6 becomes smaller as the demanded drive torque TRQ_eng is larger. Further, the cylinder intake air amount Gcyl is controlled to a value smaller than the value thereof within the range (L1), and at the same time such that it becomes larger as the demanded drive torque TRQ_eng is larger. Furthermore, the target air-fuel ratio KCMD is controlled to hold a value within the lean region mentioned above, which is richer than the values set when the demanded drive torque TRQ_eng is within the range (L1). The intake pipe absolute pressure PBA, and the main fuel injection ratio Rt_Pre are both controlled to hold the values thereof set when the demanded drive torque TRQ_eng is within the range (L1).

TRQ1<TRQ_eng≦TRQott  (L3)

In this range, according to the setting of the basic value θmsi_base described above, the auxiliary intake cam phase θmsi is controlled such that it has the same tendency as when the demanded drive torque TRQ_eng is within the range (L2). Particularly when TRQ_eng=TRQott holds, the auxiliary intake cam phase θmsi is controlled to the Otto phase value θmsiott, which means that the engine 3 is controlled to Otto cycle operation. Further, the target air-fuel ratio KCMD and the cylinder intake air amount Gcyl as well are controlled such that they have the same tendencies as when the demanded drive torque TRQ_eng is within the range (L2). Furthermore, within this range (L3), the supercharging operation is carried out by the turbocharger device 10, whereby the intake pipe absolute pressure PBA is controlled to a higher value as the demanded drive torque TRQ_eng is larger. Further, the main fuel injection ratio Rt_Pre is controlled to a smaller value as the demanded drive torque TRQ_eng is larger. In other words, as the demanded drive torque TRQ_eng is larger, the fuel injection amount Tout_sub of the auxiliary fuel injection valve 15 is controlled to a larger value. This is to attain the cooling effect by the fuel evaporation cooling device 12.

TRQott<TRQ_eng<TRQ2  (L4)

In this range, the auxiliary intake cam phase θmsi is controlled such that the degree of the advanced closing of the intake valve 6 becomes larger as the demanded drive torque TRQ_eng is larger. This is to increase the combustion efficiency by the high expansion ratio cycle operation, as described hereinbefore. Further, the cylinder intake air amount Gcyl, the target air-fuel ratio KCMD, the main fuel injection ratio Rt_Pre, and the intake pipe absolute pressure PBA are controlled such that they have the same tendencies as when the demanded drive torque TRQ_eng is within the range (L3). Particularly, the intake pipe absolute pressure PBA is controlled, similarly to the above, to a larger value as the demanded drive torque TRQ_eng is larger. This is to increase the charging efficiency through the supercharging operation to increase torque generated by the engine 3, so as to compensate for reduction of the torque which is caused when the auxiliary intake cam phase θmsi is controlled to the advanced-closing side.

TRQ2≦TRQ_eng<TRQ4  (L5)

In this range, the auxiliary intake cam phase θmsi is controlled such that the degree of the advanced closing of the intake valve 6 becomes smaller as the demanded drive torque TRQ_eng is larger, which results in an increase in effective compressed volume of intake air. This is to compensate for reduction of torque generated by the engine 3, by controlling the auxiliary intake cam phase θmsi, since as described hereinbefore, the torque generated by the engine 3 is reduced when the degree of the advanced closing of the intake valve 6 is controlled to be large in a state of the charging efficiency being reduced by the restriction of the supercharging operation.

Further, the intake pipe absolute pressure PBA is controlled to hold a fixed value in the range of TRQ2≦TRQ_eng≦TRQ3, and controlled to a smaller value, as the demanded drive torque TRQ_eng is larger in the range of TRQ3<TRQ_eng<TRQ4. Further, the main fuel injection ratio Rt_Pre is controlled to a smaller value, as the demanded drive torque TRQ_eng is larger, similarly to that within the range (L3). As described above, within the range (L5), as the demanded drive torque TRQ_eng is larger, the supercharging operation carried out by the turbocharger device 10 is restricted, and at the same time the cooling effect attained by the fuel evaporation cooling device 12 is controlled to be increased. This makes it possible to prevent knocking from occurring in the engine 3 without performing the retard control for retarding the ignition timing. It should be noted that in the case of the conventional engine provided with a turbocharger device, knocking occurs in the engine within this range (L5) of the demanded drive torque TRQ_eng, unless the retard control for retarding the ignition timing is carried out.

TRQ4≦TRQ_eng  (L6)

This range corresponds to a very high-load region, so that it is impossible to prevent knocking in the engine 3 from occurring, by the restriction of the supercharging operation by the turbocharger device 10 and the cooling effect by the fuel evaporation cooling device 12. Therefore, the retard control for retarding the ignition timing is carried out. More specifically, the target air-fuel ratio KCMD is controlled to a richer value as the demanded drive torque TRQ_eng is larger. At the same time, the auxiliary intake cam phase θmsi is controlled to the Otto phase value θmsiott; the cylinder intake air amount Gcyl is controlled to an approximately fixed value; the main fuel injection ratio Rt_Pre is controlled to the minimum value Rtmin; and the intake pipe absolute pressure PBA is controlled to hold an approximately fixed value.

As described above, according to the control system 1 of the present embodiment, the vector θs of the model parameters is identified based on the controlled object model expressed by the equation (2) with the identification algorithm expressed by the equations (8) to (13), and the SLD controller 224 calculates the target auxiliary intake cam phase θmsi_cmd according to the vector Os of the model parameter such that the cylinder intake air amount Gcyl converges to the target intake air amount Gcyl_cmd. Thus, the target auxiliary intake cam phase θmsi_cmd is calculated with the adaptive control algorithm, and hence even when dynamic characteristics of the controlled object suffers from variation or aging, due to the aging of the air flow sensor 21 or variation or aging of the dynamic characteristics of the variable intake valve actuation assembly 40, it is possible to cause the dynamic characteristics of the controlled object model to be adapted to the actual dynamic characteristics thereof while avoiding the influence thereof, and thereby cause the cylinder intake air amount Gcyl to quickly and stably converge to the target intake air amount Gcyl_cmd. This makes it possible to ensure high robustness and improve controllability in the air-fuel ratio control, whereby it is possible to avoid occurrence of torque variation and rotational variation and improve combustion state. As a result, it is possible to improve drivability and reduce exhaust emissions.

Further, the state predictor 22 calculates the predicted intake air amount Pre_Gcyl based on the controlled object model expressed by the equation (2) with the prediction algorithm expressed by the equation (7). This makes it possible to calculate the predicted intake air amount Pre_Gcyl as a value in which the dead time “d” of the controlled object is compensated for, and since the identification calculation by the onboard identifier 223 and calculation of the target auxiliary intake cam phase θmsi_cmd by the SLD controller 224 are executed using the thus calculated predicted intake air amount Pre_Gcyl, it is possible to calculate the target auxiliary intake cam phase θmsi_cmd while compensating for the dead time “d” of the controlled object. This makes it possible to improve the convergence of the cylinder intake air amount Gcyl to the target auxiliary intake cam phase θmsi_cmd, and as a result, it is possible to further improve drivability and further reduce exhaust emissions.

Moreover, the SLD controller 224 calculates the target auxiliary intake cam phase θmsi_cmd with the sliding mode control algorithm expressed by the equations (15) to (22) such that the cylinder intake air amount Gcyl converges to the target intake air amount Gcyl_cmd. Therefore, the convergence behavior and convergence speed of the cylinder intake air amount Gcyl to the target intake air amount Gcyl_cmd can designated as desired by setting the switching function-setting parameter Ss. Therefore, it is possible set the convergence rate at which the cylinder intake air amount Gcyl converges to the target intake air amount Gcyl_cmd to an appropriate value dependent on the characteristics of the controlled object, whereby the cylinder intake air amount Gcyl can be caused to quickly and stably converge to the target intake air amount Gcyl_cmd while preventing oscillatory and overshooting behaviors. As a result, it is possible to further improve drivability and further reduce exhaust emissions.

As described above, according to the control system 1 of the present embodiment, the predicted intake air amount Pre_Gcyl is calculated with the prediction algorithm expressed by the equation (7), and the compensation parameter γ1 for compensating for the steady-state deviation between the predicted intake air amount Pre_Gcyl and the cylinder intake air amount Gcyl is included as an addition term in a plurality of predictive coefficients in the prediction equation (7), so that it is possible to calculate the predicted intake air amount Pre_Gcyl as a value in which the compensation parameter γ1 is directly reflected. Further, the predictive coefficient vector θs including the compensation parameter γ1 is identified with the identification algorithm expressed by the equations (8) to (13) such that the identification error ide, which is the difference between the predicted intake air amount Pre_Gcyl and the cylinder intake air amount Gcyl, is minimized, and hence it is possible to identify the predictive coefficient vector θs as a value for causing the dynamic characteristics of the predicted intake air amount Pre_Gcyl to accurately match those of the cylinder intake air amount Gcyl, thereby making it possible to compensate for the steady-state deviation between the predicted intake air amount Pre_Gcyl and the cylinder intake air amount Gcyl. Particularly, the compensation parameter γ1 identified as described above is included in the prediction equation (7) as an addition term, which makes it possible to effectively compensate for the steady-state deviation between the predicted intake air amount Pre_Gcyl and the cylinder intake air amount Gcyl. Besides, as described above, since the compensation parameter γ1 identified as above can be directly reflected in the predicted intake air amount Pre_Gcyl, it is possible to enhance the prediction accuracy of the predicted intake air amount Pre_Gcyl.

Furthermore, the target auxiliary intake cam phase θmsi_cmd is calculated with the sliding mode control algorithm expressed by the equations (15) to (21), according to the predictive coefficient vector θs identified as described above, such that the cylinder intake air amount Gcyl converges to the target intake air amount Gcyl_cmd. Therefore, it is possible to cause the cylinder intake air amount Gcyl to quickly and stably converge to the target intake air amount Gcyl_cmd, while preventing oscillatory and overshooting behaviors. Further, when the sliding mode control algorithm is employed, the target auxiliary intake cam phase θmsi_cmd is calculated as a sum total of three inputs (Ueq+Urch+Uvt) including the valve control input Uvt, which is a feedforward term, so that even when there are two solutions (values on the advanced-closing side and the delayed-closing side) as solutions to the target auxiliary intake cam phase θmsi_cmd, the valve control input Uvt makes it possible to forcibly select one of the two solutions as a solution to the target auxiliary intake cam phase θmsi_cmd. Moreover, since the compensation parameter γ1 is included in the predictive coefficient vector θs identified by the onboard identifier 223, it is possible to cause the cylinder intake air amount Gcyl to converge to the target intake air amount Gcyl_cmd, as described above, while compensating for adverse influence of the valve control input Uvt.

Furthermore, since the variable intake valve actuation assembly 40 is formed by a hydraulically-driven type, the intake valves 6 can be more positively opened and closed in a higher load region than when using a variable intake valve actuation assembly of a type in which the valve elements of the intake valves 6 are driven by electromagnetic forces of the solenoids, and it is possible to reduce power consumption and operation noise of the intake valves 6.

Further, the combination of the intake valve actuation assembly 50 comprised of the main and auxiliary intake cams 43 and 44, the main and auxiliary intake camshafts 41 and 42, the linkage 50, and the intake air rocker arm 51, and the variable auxiliary intake cam phase mechanism 70 can realize a configuration which makes it possible to change the auxiliary intake cam phase θmsi as desired, i.e. a configuration which makes it possible to change the valve-closing timing and the valve lift of the intake valve 6, as desired.

It should be noted that when the auxiliary intake cam phase-varying mechanism 70 is not required to be high in responsiveness (e.g. when it is only required to perform only one of the delayed closing control and advanced closing control of the intake valve 6, in the aforementioned intake valve control process), the oil pressure pump 63 and the solenoid valve mechanism 64 may be used in place of the oil pressure piston mechanism 73 and the motor 74, similarly to the main intake cam phase-varying mechanism 60. In this case, the control system 1 may be configured as shown in FIG. 68.

As shown in FIG. 68, this control system 1 is provided with a DUTY_msi-calculating section 300 and a throttle valve opening controller 301, in place of the DUTY_th-calculating section 200 and the auxiliary intake cam phase controller 220. In the DUTY_msi-calculating section 300, the target auxiliary intake cam phase θmsi_cmd is calculated by searching a table according to the demanded drive torque TRQ_eng, and then the control input DUTY_msi is calculated by searching a table according to the target auxiliary intake cam phase θmsi_cmd calculated. Further, in the throttle valve opening controller 301, the target opening degree TH_cmd is calculated with the same control algorithm as that of the first SPAS controller 221 described above according to the cylinder intake air amount Gcyl and the target intake air amount Gcyl_cmd, and thereafter the control input DUTY_th is calculated with the same control algorithm as that of the second SPAS controller 225 described above according to the calculated target opening degree TH_cmd. When the control system 1 is configured as above, even if the auxiliary intake cam phase-varying mechanism 70 is low in responsiveness, it is possible to properly control the auxiliary intake cam phase θmsi, while preventing adverse influence of the low responsiveness of the auxiliary intake cam phase-varying mechanism 70.

Further, although in the above embodiment, the auxiliary intake cam phase controller 220 is provided with both the first SPAS controller 221 and the second SPAS controller 225, this is not limitative, but an auxiliary intake cam phase controller provided with only the first SPAS controller 221 may be employed. In this case, it is only required that the control input DUTY_msi is calculated e.g. by referring to a table according to the target auxiliary intake cam phase θmsi_cmd calculated by the first SPAS controller 221.

Further, although in the above-described embodiment, the sliding mode control algorithm is used in the first and second SPAS controllers 221 and 225 use as the response-specifying control algorithm, by way of example, this is not limitative, but a back-stepping control algorithm or the like may be employed insofar as it is a response-specifying control algorithm.

Further, although in the above-described embodiment, the variable intake valve actuation assembly 40 is used as the variable intake valve timing device, by way of example, this is not limitative, but any device may be employed insofar as it can change the amount of intake air drawn into the cylinder by changing the valve timing of the intake valve 6. For example, an electromagnetically-driven valve mechanism that drives the valve timing of the intake valve 6 by an electromagnetic force may be employed as the variable intake valve timing device.

Further, although in the above embodiment, the control system according to the present invention is applied to the intake system of an internal combustion engine for an automotive vehicle, as a plant, this is not limitative, but it is to be understood that the control system according to the present invention is applicable to various industrial machines as plants. Further, the control system according to the present invention is applicable not only to the internal combustion engine for an automotive vehicle, according to the above embodiment, but to internal combustion engines, such as those installed on boats.

INDUSTRIAL APPLICABILITY

As described heretofore, the intake air amount control systems for internal combustion engines, according to the first and second aspects of the present invention make it possible to ensure high robustness and improve controllability in intake air amount control, whereby it can be used to various internal combustion engines including the internal combustion engine for vehicles, as the intake air control system that can improve drivability and reduce exhaust emissions. Further, the control systems according to the third and fourth aspects of the present invention make it possible to compensate for a steady-state deviation between a predicted value of an output from a plant and a detected value of the output, whereby it can be used in various industrial apparatuses as plants, including the intake system of internal combustion engines for vehicles. 

1. An intake air amount control system for an internal combustion engine, which variably controls an amount of intake air drawn into a cylinder via a variable intake valve timing device that changes valve timing of an intake valve, as desired, comprising: estimated intake air amount-calculating means for calculating an estimated intake air amount as an estimated value of the amount of intake air drawn into the cylinder; target intake air amount-setting means for setting a target intake air amount as a target to which the intake air amount is to be controlled; identification means for identifying, based on a controlled object model to which a control command value for controlling the variable intake valve timing device is inputted and from which the estimated intake air amount is outputted, all model parameters of the controlled object model, with a predetermined identification algorithm; control command value-calculating means for calculating the control command value based on the identified all model parameters such that the estimated intake air mount converges to the target intake air amount; and control means for controlling the variable intake valve timing device according to the calculated control command value.
 2. An intake air amount control system as claimed in claim 1, wherein said control command value-calculating means calculates a predicted value of the estimated intake air amount, with a predetermined prediction algorithm, and calculates the control command value further based on the predicted value of the estimated intake air amount.
 3. An intake air amount control system as claimed in claim 2, wherein said control command value-calculating means calculates the control command value further with a predetermined response-specifying control algorithm.
 4. An intake air amount control system as claimed in claim 1, wherein the variable intake valve timing device comprises: an intake rocker arm that pivotally moves to thereby actuate the intake valve for opening and closing thereof; a movable pivot that pivotally movably supports said intake rocker arm; first and second intake camshafts that rotate at the same rotational speed; a variable intake cam phase mechanism that changes a relative phase between the first and second intake camshafts; a first intake cam that is provided on said first intake camshaft, for rotation along with rotation of said first intake camshaft to thereby pivotally move said intake rocker arm about said pivot; and a second intake cam that is provided on said second intake camshaft, for rotation along with rotation of said second intake camshaft to thereby move said pivot of said intake rocker arm.
 5. An intake air amount control system as claimed in claim 3, wherein the variable intake valve timing device comprises: an intake rocker arm that pivotally moves to thereby actuate the intake valve for opening and closing thereof; a movable pivot that pivotally movably supports said intake rocker arm; first and second intake camshafts that rotate at the same rotational speed; a variable intake cam phase mechanism that changes a relative phase between the first and second intake camshafts; a first intake cam that is provided on said first intake camshaft, for rotation along with rotation of said first intake camshaft to thereby pivotally move said intake rocker arm about said pivot; and a second intake cam that is provided on said second intake camshaft, for rotation along with rotation of said second intake camshaft to thereby move said pivot of said intake rocker arm.
 6. An intake air amount control system as claimed in claim 4, wherein said variable intake cam phase mechanism is formed by a hydraulically-driven variable intake cam phase mechanism that is driven by supply of oil pressure, and wherein said control means controls oil pressure supplied to said hydraulically-driven variable intake cam phase mechanism.
 7. An intake air amount control system as claimed in claim 5, wherein said variable intake cam phase mechanism is formed by a hydraulically-driven variable intake cam phase mechanism that is driven by supply of oil pressure, and wherein said control means controls oil pressure supplied to said hydraulically-driven variable intake cam phase mechanism.
 8. An intake air amount control system for an internal combustion engine, which variably controls an amount of intake air drawn into a cylinder via a variable intake valve timing device that changes valve timing of an intake valve, as desired, comprising: estimated intake air amount-calculating means for calculating an estimated intake air amount as an estimated value of the amount of intake air drawn into the cylinder; target intake air amount-setting means for setting a target intake air amount as a target to which the intake air amount is to be controlled; predicted value-calculating means for calculating a predicted value of the estimated intake air amount with a predetermined prediction algorithm; control command value-calculating means for calculating the control command value such that the estimated intake air amount converges to the target intake air amount, according to the predicted value of the estimated intake air amount; and control means for controlling the variable intake valve timing device according to the calculated control command value.
 9. An intake air amount control system as claimed in claim 8, wherein said control command value-calculating means calculates the control command value further with a predetermined response-specifying control algorithm.
 10. An intake air amount control system as claimed in claim 8, wherein the variable intake valve timing device comprises: an intake rocker arm that pivotally moves to thereby actuate the intake valve for opening and closing thereof; a movable pivot that pivotally movably supports said intake rocker arm; first and second intake camshafts that rotate at the same rotational speed; a variable intake cam phase mechanism that changes a relative phase between the first and second intake camshafts; a first intake cam that is provided on said first intake camshaft, for rotation along with rotation of said first intake camshaft to thereby pivotally move said intake rocker arm about said pivot; and a second intake cam that is provided on said second intake camshaft, for rotation along with rotation of said second intake camshaft to thereby move said pivot of said intake rocker arm.
 11. An intake air amount control system as claimed in claim 9, wherein the variable intake valve timing device comprises: an intake rocker arm that pivotally moves to thereby actuate the intake valve for opening and closing thereof; a movable pivot that pivotally movably supports said intake rocker arm; first and second intake camshafts that rotate at the same rotational speed; a variable intake cam phase mechanism that changes a relative phase between the first and second intake camshafts; a first intake cam that is provided on said first intake camshaft, for rotation along with rotation of said first intake camshaft to thereby pivotally move said intake rocker arm about said pivot; and a second intake cam that is provided on said second intake camshaft, for rotation along with rotation of said second intake camshaft to thereby move said pivot of said intake rocker arm.
 12. An intake air amount control system as claimed in claim 10, wherein said variable intake cam phase mechanism is formed by a hydraulically-driven variable intake cam phase mechanism that is driven by supply of oil pressure, and wherein said control means controls oil pressure supplied to said hydraulically-driven variable intake cam phase mechanism.
 13. An intake air amount control system as claimed in claim 11, wherein said variable intake cam phase mechanism is formed by a hydraulically-driven variable intake cam phase mechanism that is driven by supply of oil pressure, and wherein said control means controls oil pressure supplied to said hydraulically-driven variable intake cam phase mechanism.
 14. A control system for controlling a plant, comprising: output detecting means for detecting an output from the plant; target value-setting means for setting a target value of the output from the plant; and prediction means for predicting a predicted value of the output from the plant, with a predetermined prediction algorithm which is derived based on a controlled object model of the plant and defines a relationship between an input to the plant, the output, and the predicted value of the output from the plant, wherein the predetermined prediction algorithm includes a plurality of predictive coefficients, the predictive coefficients including a compensation parameter for compensating for a steady-state deviation between the predicted value of the output from the plant and the output from the plant, as one of an addition term and a subtraction term, the control system further comprising: identification means for identifying the predictive coefficients with a predetermined identification algorithm such that a difference between the predicted value of the output from the plant and the detected output from the plant becomes minimum; and control command value-determining means for determining a control command value for controlling an input to the plant, based on the identified predictive coefficients with a predetermined control algorithm such that the detected output from the plant converges to the set target value.
 15. A control system as claimed in claim 14, wherein the predetermined control algorithm is a predetermined response-specifying control algorithm.
 16. A control system as claimed in claim 15, wherein with the predetermined response-specifying control algorithm, the control command value is determined as a total sum of a plurality of command value components, and wherein the command value components include a selection command value component for selecting, when there are two solutions to the command control value, one of the two solutions.
 17. A control system for variably controlling an amount of intake air drawn into a cylinder of an internal combustion engine via a variable intake valve timing device that changes valve timing of an intake valve, as desired, comprising: cylinder intake air amount-detecting means for detecting a cylinder intake air amount as an amount of intake air drawn into the cylinder; target value-setting means for setting a target value of the cylinder intake air amount; and prediction means for predicting a predicted value of the cylinder intake air amount, with a predetermined prediction algorithm that is derived based on a controlled object model to which a value indicative of valve timing of the intake valve is inputted, the value being set by the variable intake valve timing device, and from which the cylinder intake air amount is outputted, and defines a relationship between the value indicative of the valve timing of the intake valve, the cylinder intake air amount, and the predicted value of the cylinder intake air amount, wherein the predetermined prediction algorithm includes a plurality of predictive coefficients, the predictive coefficients including a compensation parameter for compensating for a steady-state deviation between the predicted value of the cylinder intake air mount and the cylinder intake air amount, as one of an addition term and a subtraction term, the control system further comprising: identification means for identifying the predictive coefficients with a predetermined identification algorithm such that a difference between the predicted value of the cylinder intake air mount and the detected cylinder intake air mount becomes minimum; and control command value-determining means for determining a control command value for controlling the variable intake valve timing device based on the identified predictive coefficients with a predetermined control algorithm such that the detected cylinder intake air mount converges to the set target value.
 18. A control system as claimed in claim 17, wherein the predetermined control algorithm is a predetermined response-specifying control algorithm.
 19. A control system as claimed in claim 18, wherein with the predetermined response-specifying control algorithm, the control command value is determined as a total sum of a plurality of command value components, and wherein the command value components include a selection command value component for selecting, when there are two solutions to the command control value, one of the two solutions. 